DE2726942A1 - Laboratory pipe coupled gas flowmeter - counts bubbles as gas escapes below liq. surface by detecting sound made by each bubble - Google Patents

Abstract

A method is used for the quantitative measurement of the flow of gas through a pipe, esp. for laboratory purposes, in which the gas passes through a dip-tube immersed below the level of liquid in a vessel, escaping in the form of a regular flow of bubbles of constant volume, which are counted to give a measure of the total flow. The counting is effected acoustically as a function of the noise generated by the bubble flow. The noise produced by each bubble may be picked up by means of an electro-acoustic transducer (11) located above the liquid level (7) and the output signal may be fed to a counter (13).

Description

Designation: Method for the quantitative measurement of a through

a conduit of flowing gas stream.

Name: Method for the quantitative measurement of one by one Line flowing gas stream.

The invention relates to a method for the quantitative measurement of a gas flow flowing through a pipe, in which the gas flow is directed into a dip tube that ends below a liquid level, which per unit of time from this Pipe end emerging gas bubbles of known volume are counted and the sic Gas collecting in a space above the liquid level in a discharge line is forwarded.

Flow meters for gases, also called gas meters, are in many ways Embodiments known. Especially in laboratory practice is a method for gas quantity measurement is known in which the gas flow to be measured emerges from a pipe end which is arranged below a liquid level is. The gas bubbles emerging from this end of the pipe and rising in the liquid generally have a constant volume. Counts to them in a unit of time formed gas bubbles, one can determine the flow rate of the gas. In which known method, a person counts the rising gas bubbles in a helicopter certain period of time, which he tears off, for example, with an it (EF * clock.

The known method for gas quantity measurement is particularly suitable for flow rates that are constant over time, for example for long-term chemical experiments and leak tests. Since due to the external conditions - such as gas pressure, Size of the outflow opening - the flow rate is different in the two examples listed does not change in time, one carried out in a relatively short period of time is sufficient Measurement in order to be able to indicate the amount of gas flowing through within a longer period of time. This is particularly true when testing a gas installation in a building, to determine whether there is a leak rate in the in-house system, and the size of the leak rate that may have been found. First of all a pressure equalization between the in-house system and the city management established, then the subsequent supply line is blocked and now parallel to it Shut-off valve measured the gas flow from the supply line into the in-house network, which is necessary to avoid pressure losses in the house installation caused by leaks balance. If the house network is completely dense, the pressure in the house installation remains constant and no gas flows from the city line. However, if there is a leak in the house installation before, a certain amount of gas always flows into the house network. The size of this The amount of gas provides information about the size of the leak or leaks in the home network.

The known method for counting the ascending gas bubbles which a person counts the number of gas bubbles formed has disadvantages. A human will miscount from time to time. He can start counting again if he the counting error has become conscious, if he has not noticed the counting error, that is the case Incorrect quantity determination. So once time is lost, in the other case it is the specified flow rate is incorrect. Now you can do the count in particular facilitate a rapid succession of gas bubbles by the fact that the gas flow meter a bypass with known flow properties is connected in parallel.

However, in such a measuring method, an additional conversion is made necessary, depending on the setting of the detour, which in turn causes sources of error, in addition, such a detour is costly. Continue to be used for counting good lighting required.

The object of the invention is to overcome the disadvantages of the known method to avoid and a simple and objective method for measuring the flow of To create gases in which a gas stream flowing through a pipe even in the dark can be determined precisely, quickly and largely automatically, even by untrained people ten forces can easily be carried out.

This object is achieved in that bubble noises are recorded acoustically, converted into electrical impulses and counted electronically.

This method has the advantage that it is simple and has a good signal-to-noise ratio counting pulses triggered by the gas bubbles can be obtained with known electronic Counters can be counted. The electroacoustic transducer and the following one Microphone amplifiers can be easily adjusted to the characteristic bubble noises adapt, the electroacoustic transducer can be conveniently placed near the noise source and the counting frequency can fluctuate over a very wide range, for example between one bubble per minute and a large number of bubbles per second.

Bubbles can also be counted in non-transparent liquids for example in mercury.

On the one hand, the method is advantageous when the flow rates are constant over time, like this one, for example, in F1 .e son leakages an installation system given are. A measurement taken for a short time - e.g. within a minute - Sufficient for this application to determine the leak rate. With fluctuating Through a series of such short-term measurements, the flow rates can be measured over time Behavior of the gas flow can be queried.

On the other hand, the method offers advantages, especially for long-term measurements, because the count is automatic. Total flow rates can be easily determined, even with fluctuations in the river.

For example, if the measurement takes place over a period of one day, the total flow rate is displayed as each bubble is counted individually and the display adds up the individual bubble impulses.

As a counting device, electronic counters are advantageous, they are inexpensive, often have a self-illuminating display, they can be combined with simple Means to registration facilities, in particular printers or data processing systems, connect. On the other hand, the counting device can also be partially mechanical be used, for example, as a counting relay.

It is also proposed that the noise when forming a free gas bubble is converted. Once there is a gas bubble from the submerged end the supply pipe constricts, a characteristic noise is created, which in particular with immersed in the liquid or on the wall of the liquid container attached microphones can be easily recorded can. Farther it is also possible to hear the sound of a gas bubble bursting on the surface of the liquid to convert. One becomes that of the processes of conversion given above choose the one that is more immune to interference in the given circumstances The method is carried out starting from a liquid-filled one Hollow chamber into which a dip tube ending above the liquid level and rape in a discharge ending above the liquid level, proposed, that the wet gas meter is connected to an electronic counter electroacoustic transducer. Such a wet gas meter can be relatively set up easily and inexpensively and is uncomplicated to maintain and become.

Two embodiments of the invention are shown in the drawing and are described in more detail below. They show: FIG. 1 a longitudinal section by a hollow chamber with an electroacoustic transducer, bounded by a bottle in the gas space and the electronic counting device connected to it, FIG. 2 Cross-section through a spherical hollow chamber with connecting pieces for the electroacoustic Transducer and attached electroacoustic transducer.

The hollow chamber 1 in Fig. 1 is bounded by the interior of a bottle 2, which is closed by a cork 3. Through the Cork 3 a dip tube 4 and a discharge line 5 are passed through so that the hollow chamber 1 with blocked immersion tube 4 and blocked discharge line 5 gas- and liquid-tight is closed to the outside world.

he hollow chamber is slightly more than half covered with a transpatent Liquid 6 filled. Above the liquid level 7 of this liquid 6 there is a gas space 8. The outlet end 9 of the dip tube 4 is in the liquid 6 immersed, with complete pressure equalization between hollow chamber 1 and the outside world is thus the inside of the dip tube up to the level of the liquid mirror 7 with the liquid 6 is filled. The inlet 10 of the discharge line 5 ends within the gas space 8 below the rxor ens 3.

In the gas space 8 and approximately below the center of the cork 3 is an electroacoustic one Converter 11 attached to the cork 3, and via an electrical supply line to a counter 13 connected.

In operation, the wet gas meter shown works as follows: ird the input 14 of the immersion tube 4 is subjected to a gas pressure which corresponds to that at the outlet 15 of the outlet 5 exceeds the prevailing gas pressure, the liquid column in the immersion tube 4 pressed down, at the outlet end 9 of the immersion tube 4 blows are formed, which pinch off and rise individually to the top and burst at the liquid level 7. The gas collects in the space 8, enters the inlet 10 of the discharge line 5 and leaves these Lead 5 at its output 15. The electroacoustic converter 11 is arranged above the point of the liquid level 7 at which the gas bubbles 16 burst. The resulting noise is converted into an electrical signal and fed to the input of the counter 13 by means of the supply line 12.

The counter 13 is released either shortly before the start of the measurement and the counting process triggered by the first bubble signal, or the counting process is started manually after a few bubbles have formed. With the start of the counting process the clock of the counter 13 begins to run and this registers it in a unit of time ascended gas bubbles 16. If the volume of the gas bubbles 16 is known, then it knows the flow rate per time is also heated. The counter can advantageously directly calibrated in flow rates. The counting process is stopped by a clock in the counter controlled automatically after a specified time unit has elapsed or is manual interrupted. The flow rate remains on the counter at least for a certain time 13 displayed.

In the second embodiment of FIG. 2, the hollow chamber 1 of a glass ball 17 limited. Through the wall of this glass ball 17 are three tubes passed through and fused tightly to the glass ball 17 on its outside. The outlet end 9 of the immersion tube 4 protrudes approximately 2/3 into the hollow chamber 1 into it.

At an angle of 900 to the immersion tube 4 and also perpendicular to the wall The discharge line 5 is arranged on the glass ball 17. This derivation 5 sti = at in inside and outside diameter with the corresponding dimensions of the immersion tube 4 match.

It is on the bisector between dip tube 4 and discharge line 5 a connecting piece 18 is formed, which is used for acoustic coupling and fastening of the electroacoustic Converter 11 is used. This electroacoustic transducer ii is at a short distance Above the nozzle 18 arranged, but touch this nozzle 18 z. Converter 11 and connector 18 are gas-tight and watertight by means of a shrink hose 19 connected with each other.

To protect the electroacoustic transducer 11 from moisture and wetness protect, it is surrounded by a film 20. over the outside ends of the dip tube 4 and the derivative 5 are each e; Hose 21,22 put over through which the inlet and Derivation of the gas flow to be measured takes place. The hoses 21, 22 are made of soft, the sound propagation inhibiting material produced.

This is a feed line for interfering noises via the installation lines of the system to be examined and also the acoustic reflection of bubble noises suppressed in this system, i.e. the measuring chamber is acoustically isolated. For sound insulation the ball 17 and its fixed extremities are in a sound-absorbing material 23 embedded.

In the simplest case, the electroacoustic transducer 11 can also directly the input of a counter 13 are connected. To interfering signals also electrically suppress as much as possible can, however, is an advantage to process the pulses emitted by the electroacoustic transducer 11 first. Therefore, a bandpass filter is expediently connected in front of the input of the counter 13, which is adapted in its frequency behavior to the bubble noise. In addition, a Pulse shaper stage, for example a Schmitt trigger inserted, the pulses below negated a threshold voltage and thus keeps background noises away from the counter 13.

The electroacoustic transducer 11 can also be in a side window Immersion tube 4 or be arranged in the hose 21. Likewise is an arrangement possible in the discharge line 5 or the hose 22, for example by means of a T-piece, in the third end of which the electroacoustic transducer is housed.

LIST OF REFERENCE NUMERALS 1 hollow chamber 15 exit of the outlet 2 bottle 16 gas bubbles 3 corks 17 glass ball 4 immersion tube 18 nozzle 5 discharge 19 shrink tube 6 Liquid 20 Foil 7 Liquid level 21 Hose on immersion tube 8 Gas space 22 hose on discharge line 9 outlet end of immersion tube 23 sound-absorbing material 10 inlet of discharge line 11 electroacoustic transducer 12 feed line 13 counting device 14 Inlet of the immersion tube

Claims (13)

PATEN TAN PROBLEMS 1 Method of quantitative measurement of a by a conduit for flowing gas flow, in which the gas flow is directed into a dip tube that ends below a liquid level, which per unit of time from this Pipe end emerging gas bubbles of known volume are counted and that themselves Gas collecting in a space above the liquid level in a discharge line is passed on, characterized in that caused by the gas bubbles Noises are recorded acoustically, converted into electrical impulses and electronically are counted. 2. The method according to claim 1, characterized in that the noise is absorbed when a free gas bubble is formed. 3. The method according to claim 1, characterized in that the noise is absorbed when a gas bubble bursts on the liquid surface. 4. wet gas knife for performing the method according to any one of the claims 1 to 3, consisting of a hollow chamber filled with liquid into which a Immersion tube ending below the liquid level and one above the liquid level protruding ending lead, characterized in that it has an electronic Counting device (13) has connected electroacoustic transducer (11). 5. wet gas knife according to claim 4, characterized in that the electroacoustic Converter (11) is arranged in the gas space (8) above the liquid level (7). 6. wet gas knife according to claim 5, characterized in that the electroacoustic Converter (11) is arranged in the immersion tube (4). 7. wet gas knife according to claim 5, characterized in that the electroacoustic Converter (11) is arranged in the discharge line (5). 8. wet gas knife according to claim 4, characterized in that the electroacoustic The transducer (11) is immersed in the liquid (6). 9. wet gas meter according to claim 5, for a leak test device for Testing of gas installations with a hollow chamber designed as a glass sphere, too the wall of which is the immersion tube and discharge pipe vertically and one below the other on the right Are arranged enclosing angles, characterized in that between the dip tube and derivation, the spherical wall merges into an outwardly pointing nozzle (18), the electroacoustic transducer (11) as an extension of the connector (18) to the outside is arranged and electroacoustic transducer (11) and nozzle (18) from a common, heat-shrinkable plastic tube (19) are covered. 10. wet gas knife according to one of claims 4 to 9, characterized in that that between the electroacoustic transducer (11) and the electronic counter (13) a band-pass filter matched to the frequency of the bubble noise is attached is. 11. wet gas knife according to one of claims 4 to 10, characterized in, that between the electroacoustic transducer (11) and the electronic counter (13) a pulse shaper, for example a Schmitt trigger, is arranged. 12. wet gas knife according to one of claims 4 to 11, characterized in that that a clock is connected to the start and stop device of the counting device (13) is. 13. Wet gas knife according to one of claims 4 to 12, characterized in that that the inlet (14) of the dip tube (4) and the outlet (15) of the outlet (5) with one tube made from a material that inhibits the propagation of sound (21,22) are connected and the outside of the hollow chamber (1) in sound-absorbing Material (23) is embedded.