NL9400108A - Apparatus for determining the flow rate of the amount of gas dispensed - Google Patents

Abstract

Apparatus for determining the volumetric amount of dispensed gas at a particular connection of a gas grid, the gas in the gas grid being under a specific high pressure. The pressure of the gas to be dispensed is reduced to slight excess pressure above normal pressure. The apparatus comprises a device for reducing the pressure of the supplied gas to the pressure of the gas to be dispensed, and a volumetric gas meter for determining the volume of gas which has flowed through. Placed in series with the volumetric gas meter is a sonic nozzle. The reducing device controls the pressure as a function of the pressure measured downstream of the sonic nozzle. A capacity limiter defines the maximum permissible pressure in the meter with the aid of the reducing device. A volume-deriving instrument is used to determine the flow rate under standard conditions from the data of the meter and the measured reference pressure.

Description

Short Title: Device for determining the flow rate of the quantity of released gas.

The invention relates to a device for determining the volumetric amount of gas released at a particular connection of a gas network, wherein the gas in the gas network is under a certain high pressure and the pressure of the gas to be delivered must be reduced to a certain desired small overpressure above the normal atmospheric pressure, the device comprising a device for reducing the pressure of the supplied gas to the desired pressure of the gas to be delivered, a volumetric gas meter for determining the volume of gas flowing through.

The gas companies that supply gas to their customers distribute the gas via a pipeline network to the off-take point where a customer wants to extract gas from the pipeline network. The customer then pays depending on the volume of the quantity of gas purchased, to which the gas companies install volume meters. For this purpose, the gas is supplied via the pipeline network to the tap point at a certain overpressure, for example 3 atmospheres, above atmospheric air pressure, after which the gas is lowered to a desired overpressure above atmospheric pressure by means of a control device after the tap point, for example. A volumetric meter is then included in the pipeline after the tap point to determine the amount of gas taken off. Well known meters used to determine the amount of gas released are, for example, turbine meters, vortex meters, displacement meters, such as those of the rotary piston or diaphragm type and other volume determining gas meters. The normally applied arrangement therefore consists in that the pressure is only reduced to a certain desired pressure with the regulator after the draw-off point, and then the gas, reduced to the desired overpressure, flows through the volumetric gas meter; in the meter again a slight pressure drop of the gas occurs, which pressure drop is, however, negligible.

A drawback of the known meters is that the meter can only be used properly within a certain measuring range, between a certain lower limit and a certain upper limit. As soon as the amount of gas that the meter flows through becomes too large, the known volumetric gas meters will run wild and will therefore not give a correct indication of the volumetric amount of gas that the meter has flowed through, but will also show defects, because the meters against overload are not resistant.

The object of the invention is to increase the measuring range of the known volumetric gas meters, so that smaller volumetric meters, and thus cheaper, can be used than has hitherto been used.

This object of the invention is achieved in that a sonic device such as a sonic nozzle is placed in series with the volumetric gas meter. With this measure it is achieved that the volumetric meter measures the flow from a small minimum amount to a certain maximum amount of gas that the meter passes. Above a certain amount of gas, due to the use of a sonic nozzle, the pressure of the gas increases, but the speed of the gas can no longer increase, so that the density of the gas increases. The measurement of the flow rate should therefore be corrected. This is done with the aid of a volume conversion instrument on the basis of data of pressure and temperature near or in the meter. Such instruments are already widely used in volumetric meters if the pressure in the meter varies over time. With the device according to the invention, the normal measuring range can be greatly expanded and a smaller meter can be used for the same measuring range as before than usual to date.

The invention will be explained in more detail with reference to the drawing. In the drawing shows:

Fig. 1 a conventional arrangement for determining the volumetric amount of gas;

Fig. 2 the arrangement according to the invention for determining the volumetric amount of gas; Fig. 3 a cross section through a sonic nozzle;

Fig. 4 an arrangement according to the invention, in which a capacity limiter is included in the arrangement.

Figure 1 shows a conventional arrangement 1 for determining the amount of gas delivered to a particular connection or customer. The gas is supplied via a pipe 2 and a shut-off valve 3 at a certain overpressure above atmospheric air pressure at a tap point, after which the gas after the tap point with the aid of a regulating device 4, for example a pressure reducing valve, to a desired overpressure above atmospheric pressure is lowered. In order to be able to determine the amount of gas delivered, a volumetric meter 6 is included in the pipe 5 after the tap point and then a valve 7. Well-known meters that are normally used for determining the amount of gas released are, for example, turbine meters, vortex gauges, displacement gauges, such as those of the rotary piston or diaphragm type and other volume determining gas gauges. The normally applied arrangement therefore consists in that the pressure is only reduced to a certain desired pressure with the aid of the regulator 4 after the collection point, and then the gas reduced to the desired pressure flows through the volumetric gas meter 6, whereby again a slight pressure drop of the gas will occur as a result of the design of the meter. The volume that is delivered is determined with the aid of the meter.

Because the state of the gas, both pressure and temperature, can vary in the meter, a volume conversion instrument is often also used, which can determine one or more variables such as the pressure and the temperature and the measured amount of volume on the basis of the measured quantities. can be traced to a volume at standard variable.

Figure 2 shows an arrangement according to the invention. The device also consists of a reducing device or control device 4, behind which a volumetric meter 6 is placed. A sonic device or nozzle 8 is placed directly behind the meter.

Figure 3 shows a cross-section of a sonic nozzle as it can be used in the arrangement according to the invention. A sonic nozzle or sonic device 8 is a generally known device which consists of a kind of venturi tube. The sonic nozzle used here has an inflow opening 9 of any cross-section, the cross-sectional area of which is much smaller than the cross-section of the gas supply tube 10. The pipe then gradually extends over a certain part 11 to the desired diameter.

Figure 4 shows an arrangement for determining the vulumetric quantity of released gas, in which an capacity limiter 13 is included, which influences the control device for regulating the pressure of the gas to the customer as soon as a certain desired maximum pressure has been built up. between the meter 6 and the sonic nozzle 8. As a result, the pressure at the location of the meter cannot rise higher than desired and the pressure is limited upwards. For example, a needle valve 15 is included in the feedback line 14 to the control device for the proper functioning of the control device 4. A volume conversion instrument 16 is connected to the meter 6 and is supplied on the one hand via the line 1.7 with the flow rate data under operating conditions from the meter 6 and on the other side via the line 18 with the reference pressure data. Using this data, the volume conversion instrument 16 gives the correct value for the flow rate or volume that has been delivered in a known manner.

The operation of the device is now as follows:

With a small gas flow, the meter will operate normally and indicate the volume of gas flowed through. Thus, at a low flow rate, the device will operate just like the conventional device as shown in Figure 1.

At a certain higher flow rate of the gas, the velocity in the sonic nozzle will reach the velocity of sound and after this the velocity in the throat of the sonic nozzle will not increase when the pressure in front of the throat of the nozzle increases. However, the gas will be compressed, so that a larger mass will flow through the throat of the nozzle.

After the nozzle, the pressure of the gas will decrease again, because the cross-section of the nozzle widens. Preferably, the sonic nozzle is dimensioned such that the cross-sectional area of the throat is equal to or less than the cross-sectional area of the throat, with maximum load on the volumetric gas meter.

Claims (6)

An apparatus for determining the volumetric amount of gas released at a particular connection of a gas network, wherein the gas in the gas network is under a certain high pressure and the pressure of the gas to be delivered must be lowered to a certain desired small overpressure above normal atmospheric pressure, which device comprises a device for reducing the pressure of the supplied gas to the desired pressure of the gas to be delivered, a volumetric gas meter for determining the volume quantity of gas flowing through, characterized in , that a sonic device such as a sonic nozzle is placed in series with the volumetric gas meter. Device according to claim 1, characterized in that the reducing device controls the pressure depending on the measured pressure delivered after the sonic nozzle. Device according to claim 1 or 2, characterized in that a capacity limiter (13) determines the maximum allowable pressure after the meter but before the sonic nozzle and controls the regulator. Device according to any one of claims 1, 2 or 3, characterized in that, using a volume conversion instrument, the data from the meter and the measured reference pressure showed the correct flow rate flowing through the meter under standard conditions determined. Device according to any one of the preceding claims, characterized in that the meter and the sonic nozzle are assembled into an instrument. Device according to any one of the preceding claims, characterized in that the cross-sectional shape of the throat of the sonic nozzle is arbitrary, i.e., for example, circular or rectangular.