DEV0004796MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: July 26, 1952. Advertised on May 24, 1956

GERMAN PATENT OFFICE

The known gas flow meters have a pressure loss, especially when there is a high gas consumption Exceeds 15 mm water column. With the two- or four-chamber meters this is a high pressure loss mainly due to the unfavorable management of the gas flow within the meter. The Gas not only has to pass through places with a small cross-section, but also suffers multiple diversions its direction of flow. This creates vortices in many places to overcome them a noticeable amount of energy is withdrawn from the gas. ■

The invention is a gas meter with low pressure loss after Chamber principle in which the gas flowing directly into a chamber is passed through suitable The shape of the inlet channel and the chamber forms a main vortex, which when opened the chamber through its centrifugal force without changing its direction of rotation flows off the outlet nozzle.

The present invention is characterized by a particularly simple gas flow management. the When filling a chamber, especially with high gas consumption, gas vortices are unavoidable in addition, while avoiding secondary eddies, so that he can use his kinetic energy when later emptying of the chamber at least for

609 527/237

V 4796 IX / 42 e

Part can release again in the direction of flow of the outlet nozzle. Figs. Ι to 5 are intended to explain the essence of the present invention in the example of a two-chamber meter. The gas meter with the inlet connection 1 and

' The outlet connection 2 has five mutually gas-tight spaces 3, 4, 5, 6, 7. 3 is the at 1. closed entry room ,. 4 the exit space connected to 2. 5 and 6 are the two measuring chambers, of which only the front one can be seen in Figs. 1, 2 and 4, and 7 is the measuring chamber, which can be in communication with the outside space. The membrane 8 sealing the measuring chambers 5, 6 from one another moves in Fig. 1, 2 and 4 in a direction perpendicular to the plane of the drawing, in Fig. 3 and 5 in the plane of the drawing from left to right (Fig. 5) or from right to left (Fig. 3). The arrows drawn in all figures indicate the main features of the flow field of the gas stream. The spaces 3 and 4 are closed off from the chamber spaces 5 and 6 by a valve system which is formed from two flat pieces 10, 11 sliding gas-tight on a grate 9 and a double lever 12 that rotates in the two-point bearing 13. A flexible sealing leather 14 is attached to this, which seals the spaces 3 and 4 from one another. In the valve plates 10 and 11 and in the grate are open, <; Connections attached in such a way that in the valve end position either chamber 3 with S and chamber 6 with 4 (Fig. 2 and 3) or chamber 3 with 6 and chamber 5 with 4 (Fig. 4 and 5) are connected. As soon as the membrane 8 has reached a certain end position deviating from the gas pressure, a tear-off device 16 is released via the transmission mechanism 15, so that the valve system 9, 10, 12, following the pressure of the valve spring 17, which has now been tensioned, jumps into the other valve end position and thereby the full chamber to empty and the empty chamber begins to fill. Another coupling 18, 19, which can also be magnetic, for example, transmits the movement of the valve system to the pulse counter 20, which measures the number of diaphragm strokes.

If now, for example, as in Fig. 2 and 3, the front chamber 5 is filled, with the membrane towards the rear recedes, the inflowing gas forms

50, a large one marked by arrows 21 Vertebra, whose older parts, marked by arrow 22, are close in the rear part of chamber 5 the membrane. As soon as the way to the outlet space 4 is clear after filling the chamber 5

55. is given (Figs. 4 and 5), the young part of the Vertebra in the outlet port. With further emptying of the chamber 5 can finally also the older part of the vortex marked by arrow 24 its kinetic energy, if still available, dispense into the outflow channel. In the now filling chamber 6, the process is repeated: A vortex 25 is formed, the older part 26 of which follows the receding membrane 8.

Claims (6)

Paten tans p Ruch Et 1. Gas meter with 'low pressure loss according to the chamber principle, characterized in that the direct route into a Gas flowing into the chamber through suitable shaping of the inlet channel and the Chamber forms a main vortex, which when the chamber is opened by its centrifugal force flows directly from the outlet connection without changing its direction of rotation. 2. Gas meter according to claim 1, characterized in that its inlet port the gas flow leads directly to the separate entrances to the two chambers and two separate outlets of both chambers open directly into the outlet nozzle. 3. Gas meter according to claim 1 and 2, characterized in that it consists of four against each other gastight main rooms is formed. 4. Valve system for the counter characterized according to claim 1 to 3, characterized in that it acts on a total of four openings, two of which are alternately opened and closed, such that there is always a measuring chamber directly with the input space and only with this and the other Measuring chamber with the exit space and only with this in connection. 5. Valve system according to claim 4, characterized in that one in the inlet space and a slider working in the exit space is coupled to one another by means of a fine double lever are, whereby this double lever rotates around a two-point bearing on which a flexible Wall is attached to the gas-tight separation of the inlet space from the outlet space. 6. Gas meter according to claim 1 to 5, characterized in that the valve switching time is short compared to a chamber filling time that it continues to be independent of gas consumption each switchover only takes place "when the membrane has traveled a precisely prescribed distance and the counter only measures the number of diaphragm strokes. 1 sheet of drawings © 609 52T / 23T 5.56