EP3717139B1 - Device and method for odorizing a gas stream in a gas line - Google Patents

Description

The invention relates to a device for odorizing a gas flow in a gas line, comprising an injection device for injecting a liquid odorant into the gas flow flowing through the gas line and a method for odorizing a gas flow in a gas line.

In the case of pipeline-based supply of natural gas to the general public, which is essentially odorless in the processed state, for safety reasons it is required that the natural gas has a sufficient odor so that any leaks in the pipeline network are subjectively perceptible to humans.

If the processed natural gas does not have a sufficient warning odor, it must be odorized in accordance with legal regulations (cf. for Germany, for example, DVGW worksheet G 280). For this reason, it is known and customary to add odorants to natural gas. Substances with a sufficient warning odor, which give the natural gas a sulfur-like odor, usually come into consideration as odorants. An example of a widely used odorant is tetrahydrothiophene (THT). Furthermore, low-sulfur and sulfur-free odorants have also been used for a number of years.

Normally, natural gas is provided in the gas transport networks (long-distance transport lines) without odorant. Odorization is then carried out by the gas network operator of the gas distribution network in question when the gas is withdrawn from the gas transport network and its pressure is reduced to the pressure prevailing in the gas distribution network. For this purpose, a liquid odorant is typically added via an odorization system in a local gas pressure control and measuring system (GDRM system). The addition takes place depending on the size of a standardized gas volume flow calculated from the data of the gas meter and the gas temperature and the gas pressure. A corresponding amount of odorant is fed by means of a pulse-controlled metering pump to an inoculation nozzle, which is designed as a dip tube with an evaporation body inserted into the line, to which the odorant fed to the inoculation nozzle is applied in liquid form. Typically, the odorant is added in proportion to the amount of gas that has flowed through. In Germany, for example, the odorant THT is supplied to the gas flow ^{with a value of at least 10 mg / m 3 gas volume.} For other odorants different, sometimes lower limit values apply. Care must be taken that a predetermined limit value, for example of 10 mg / m ³ for THT, is not fallen below during the entire distribution of the gas. The odorant is typically supplied intermittently with the immersion tube inserted into the gas line, the immersion tube being flowed around by the natural gas flowing through the gas line. The liquid odorant evaporates from the evaporation body and is absorbed by the natural gas.

Since the surface of the evaporation body of the inoculation nozzles is quite small, the odorant is not atomized when it is injected into the dip tube and the odorant is fed discontinuously or intermittently in the direction of the weight force to the dip tube, it cannot be ruled out that the odorant supplied is not completely on or in the Immersion tube evaporates and that significant quantities of liquid odorant are entrained by the gas flow and distributed in an uncontrolled manner in the gas line. In practice, it has already occurred that significant quantities of liquid odorant collect in the gas line below the injection nozzle.

To solve this problem, the EP 2 933 015 A1 a device for odorizing a gas flow in a gas network is known, in which the odorant injected into the gas line is applied to a specifically designed and arranged evaporation body in order to achieve continuous evaporation of the odorant, even if the odorant is applied discontinuously in liquid form to the evaporation body will.

However, it has been shown that such passive evaporation from an evaporation body has hitherto been limited to certain gas volume flows, so that in the case of high gas volume flows, adequate odorization may not be guaranteed or that there is an uncontrolled distribution of odorant in the gas line.

From the EP 2 933 015 A1 It is also known to atomize the odorant upstream of the evaporation body by means of a single-fluid pressure nozzle. However, it has been shown that, depending on the gas volume flow and odorant throughput, this can also lead to inadequate odorization or an uncontrolled distribution of odorant in the gas line.

Another device for odorizing a gas stream is from the U.S. 2,979,389 famous.

Against this background, the present invention is based on the object of providing a device and a method for odorization of a gas flow in a gas line, which over a broader volume flow range or at least over an alternative volume flow range reliably and trouble-free odorization of the gas flow within the legally prescribed Limit values enabled.

This object is achieved according to the invention in a device for odorizing a gas flow in a gas line, comprising an injection device for injecting the liquid odorant into the gas flow flowing through the gas line, in that the injection device has a two-substance nozzle, the device having means for providing a nozzle gas flow for having the operation of the two-substance nozzle, the means for providing the nozzle gas flow for the operation of the two-substance nozzle comprising a nozzle feed line branching off from the gas line, through which part of the gas flow flowing through the gas line is used as Nozzle gas flow is guided to the two-substance nozzle, with a gas preheater being integrated into the nozzle feed line, in particular with a vortex tube. The injection device can be designed, for example, in the form of a dip tube for immersion in a gas line into which a two-substance nozzle is integrated.

Furthermore, the above-mentioned object is achieved according to the invention by a method for odorizing a gas flow in a gas line, in which a liquid odorant is injected into the gas flow flowing through the gas line by means of a two-substance nozzle.

In addition, the above-mentioned object is achieved by using a two-substance nozzle for odorizing a gas flow in a gas line.

With a two-substance nozzle, in particular a two-substance pressure nozzle, the odorant can be atomized very finely, so that a large surface area of the odorant is provided, through which the evaporation process or the odorization process is improved, so that the odorant can completely evaporate without depositing on the gas line wall . The two-substance nozzle is therefore in particular an atomizer nozzle.

A two-substance nozzle has the advantage over a single-substance nozzle that it can reliably atomize much smaller quantities of odorant and is therefore suitable for odorising lower gas volume flows. This is made possible in that in the case of the two-substance nozzle, in addition to the odorant to be atomized, a further fluid, in particular a gas, is passed through the two-substance nozzle, through which the energy required for atomization is provided. Single-substance nozzles no longer work properly with comparably low volume flows of odorant and therefore do not atomize the odorant optimally.

To further improve the evaporation performance, an evaporation body can also be provided in addition to the two-substance nozzle, to which the odorant is applied with the two-substance nozzle. Since the odorant is applied to the evaporation body by means of a two-substance nozzle, better distribution of the odorant on the evaporation body can be achieved through the atomization of the odorant through the two-substance nozzle.

The device can be integrated into a GDRM system, for example. Since the two-substance nozzle ensures reliable operation over a wide

Permitted gas volume flow range, reliable odorization is guaranteed for different gas flows.

Various embodiments of the device and the method are described below, the individual execution methods each being applicable individually to the device, the use and the method. Furthermore, the individual embodiments can be combined with one another.

In one embodiment, the device has means for storing a liquid odorant, such as, for example, a tank. The means for storing a liquid odorant are preferably connected to the two-substance nozzle via a line in order to supply the two-substance nozzle with the odorant. A metering pump is preferably provided with which the odorant can be pumped from the means for storing the liquid odorant to the two-substance nozzle. The metering pump is preferably controlled as a function of the gas volume flow in the gas line, so that an odorant throughput which is dependent on the gas volume flow in the gas line, in particular an odorant throughput proportional to the gas volume flow, is set. For this purpose, a control device is preferably provided which is set up to receive a value for the gas volume flow in the gas line from a gas meter integrated in the gas line and to control the metering pump as a function of this value.

According to the invention, the device also has means for providing a nozzle gas flow for operating the two-substance nozzle. As a result, the two-substance nozzle is supplied with the fluid required for atomization in the form of a nozzle gas flow. In a corresponding embodiment of the method, the two-substance nozzle is operated with the liquid odorant and with a nozzle gas stream.

According to the invention, the means for providing the nozzle gas flow for the operation of the two-substance nozzle comprise a nozzle feed line branching off from the gas line, through which part of the gas flow flowing through the gas line is guided as a nozzle gas flow to the two-substance nozzle. This has the advantage that a separate gas source, for example in the form of a pressurized gas cylinder, can be dispensed with and instead the gas flowing through the gas line can be used to operate the two-substance nozzle. The nozzle feed line can be connected to the gas line via a three-way flange, for example. In a corresponding embodiment of the method, the nozzle gas stream is branched off from the gas stream flowing in the gas line, in particular before a pressure reduction of the gas stream flowing in the gas line.

In a further embodiment, the branch of the nozzle feed line is arranged in front of a control valve for pressure reduction in the gas line and the two-substance nozzle is arranged behind a control valve in the direction of flow. The nozzle feed line therefore represents in particular a bypass to the control valve in the gas line. In a GDRM system or at a transfer point from the gas network of the gas supplier to the gas network of the customer, for example to the gas network of an industrial plant or a house, one or more control valves are typically provided with which the gas pressure from the gas upstream gas network is reduced to the operating pressure of the gas downstream gas network. In an upstream local gas network for supplying a system or a house, the pressure upstream of the control valve (pre-pressure) can be, for example, in the range 20 to 50 bar, but in an upstream long-distance line it can also be up to 100 bar. The operating pressure to which the control valve reduces the gas pressure can be in the range 20 to 50 bar in the case of a local downstream gas network, and in the case of a downstream gas network an industrial plant in the range of 12 to 16 bar or in the case of a downstream gas network of a private house even only 23 mbar.

By arranging the branch of the nozzle feed line upstream of the control valve, i.e. on the upstream pre-pressure side, and the two-substance nozzle downstream of the control valve, i.e. on the downstream side with the lower pressure, there is a pressure gradient between the gas from the nozzle feed line, which the Two-substance nozzle is supplied, and the gas in the gas line at the location of the two-substance nozzle, so that energy is available for operating the two-substance nozzle and for fine atomization of the odorant. In this way, the energy of the gas flow in the gas line can be used to operate the two-substance nozzle, so that an external energy supply, for example by a compressor, is unnecessary.

In a further embodiment, a control valve is integrated into the nozzle feed line. The control valve is set up in particular to reduce the pressure in the nozzle feed line to such an extent that a pressure difference suitable for operating the two-substance nozzle is achieved with respect to the gas line at the location of the two-substance nozzle. A typical differential pressure between the gas fed into the two-substance nozzle and the pressure of the gas stream to be odorized at the location of the two-substance nozzle can be, for example, in the range from 2 to 6 bar.

The control valve in the nozzle feed line is preferably set up to adjust the pressure as a function of the volume flow through the gas line. In this way it is possible to adapt the operation of the two-substance nozzle to the gas volume flow in order to inject the appropriate amount of odorant for the corresponding gas volume flow. For this purpose, means for metering the liquid odorant depending on the size of the gas volume flow conveyed through the gas line of the gas network can be provided, for example a metering pump, for example regulated via one integrated into the gas line Gas meter to inject the appropriate amount of odorant for the gas volume flow.

In a further embodiment, a safety shut-off valve is integrated into the nozzle feed line. The safety shut-off valve is set up in particular to interrupt the volume flow flowing through the nozzle feed line when the pressure in the nozzle feed line rises above a certain limit value. In particular, the safety shut-off valve is provided behind the control valve in the nozzle feed line. In this way, if the control valve fails, it can be prevented that the pre-pressure from the gas line reaches the area of the gas line behind the control valve of the gas line via the nozzle feed line. In this way, the security of the system is guaranteed, especially since, for example, domestic and industrial installations are typically only designed for lower pressures than, for example, the pressures prevailing in the gas supply line of the gas supplier.

According to the invention, a gas preheater is integrated into the nozzle feed line, in particular upstream of the control valve. By reducing the pressure of the gas in the nozzle supply line, the Joule-Thomson effect results in cooling, which can, for example, lead to the control valve in the nozzle supply line or the two-substance nozzle icing up, so that their operation is impaired, as well as the evaporation conditions of the odorant can worsen. By providing a gas preheater, heat can be supplied to the gas flow through the nozzle feed line in order to weaken or compensate for the cooling effect. This can improve the evaporation conditions of the odorant and ensure trouble-free operation of the two-substance nozzle.

The gas preheater can comprise a vortex tube, for example. This has the advantage that the gas flow can be heated without an external energy source. How a vortex tube works for gas preheating (Ranque-Hilsch vortex tube) is known in principle, for example from EP 2 996 010 A1 , and therefore does not need to be explained in detail at this point.

In a further embodiment, the branch of the nozzle feed line is arranged behind a gas meter. In this way, the gas volume flow can be measured before part of the gas volume flow is branched off from the gas line. Alternatively, if the branch of the nozzle feed line is arranged in front of a gas meter, an additional gas meter can also be provided in the nozzle feed line so that the total gas consumption can be reliably determined by adding up the values determined by the two gas meters.

In a further embodiment, shut-off valves, for example ball valves, are integrated into the nozzle feed line in order to be able to shut off a region of the nozzle feed line. In this way, maintenance of the nozzle feed line is possible without having to interrupt the gas supply. In particular, the control valve, the safety shut-off valve and / or a possibly provided preheater and / or a possibly provided gas meter are integrated in the area between the shut-off valves, so that these components can be serviced without impairing the gas supply.

In a further embodiment, at least one controllable shut-off valve, for example a solenoid valve, is integrated into the nozzle feed line and a control device, for example the control device for controlling the metering pump, is set up to close the controllable shut-off valve when the gas volume flow in the gas line falls below a predetermined limit value falls or if no gas volume flow is measured in the gas line. In this way it can be prevented that the pressure in the gas line rises behind a control valve through the nozzle feed line when there is no or only a very low gas volume flow in the gas line.

Further features and advantages of the present invention emerge from the following description of exemplary embodiments, reference being made to the accompanying drawings.

Fig. 1

ein Beispiel einer Vorrichtung zur Odorierung eines Gasstroms,

Fig. 2

ein weiteres Beispiel einer Vorrichtung zur Odorierung eines Gasstroms,

Fig. 3

ein Ausführungsbeispiel der erfindungsgemäßen Vorrichtung,

Fig. 4a-b

zwei mögliche Ausgestaltungen für Zweistoffdüsen zur Verwendung bei den Vorrichtungen aus Fig. 2 und 3.

Show in the drawing

Fig. 1

an example of a device for odorising a gas stream,

Fig. 2

another example of a device for odorizing a gas flow,

Fig. 3

an embodiment of the device according to the invention,

Figures 4a-b

two possible configurations for two-substance nozzles for use in the devices Fig. 2 and 3 .

Figure 1 shows first of all the basic structure of a device for odorizing a gas flow in a schematic representation.

In Figure 1 a pipe section 1 of a gas line 2 is shown, which is connected downstream of a gas meter 3 in the flow direction of the gas. The device for odorization can be arranged, for example, in a GDRM system of a local gas distribution network. In the present case, natural gas is provided in the gas line 2 from a high-pressure transport network for the gas pressure distribution network at a reduced pressure.

In the direction of flow behind the gas meter 3, a liquid odorant, for example in the form of THT, is introduced into the gas line 2 via an injection device 4.

For this purpose, the odorant is taken from an odorant container 5 and fed to the injection device 4 via a metering pump 6. The metering pump 6 is connected to the gas meter 3 via a control device 7. The gas meter 3 supplies the control device 7 with information about the gas volume flow in the gas line 2 and the control device 7 controls the metering pump 6 in such a way that the metering pump 6 delivers an amount of odorant to the injection device 4 that is adapted to the gas volume flow. To regulate the metering pump 6, a flow meter 9 can be provided which measures the odorant volume flow pumped by the metering pump 6. Furthermore, a level meter 10 can be provided in order to monitor the level in the odorant container 5. A non-return valve 11 is preferably provided between the metering pump 6 and the injection device 4 in order to prevent a gas flow from the gas line 2 to the odorant container 5.

Figure 2 shows a further example of a device for odorizing a gas flow. The device 20 for odorizing a gas flow 21 in a gas line 22 comprises an odorant container 24 which is connected via a metering pump 26 to an injection device 30 integrated into the gas line 22 downstream of a control valve 28. The metering pump 26 is preferably analogous to Fig. 1 Controlled via a gas meter 32 arranged in the gas line 22 and a control device 34 such that an amount of odorant adapted to the gas volume flow in the gas line 22 is transported from the odorant container 24 through the metering pump 26 to the injection device 30. Furthermore, analogous to Fig. 1 For example, a flow meter 6 and fill level meter 10 connected to the control device 34 or a non-return valve 11 arranged between the metering pump 26 and the injection device 30 can also be provided.

The injection device 30 comprises a two-substance nozzle 36 which is arranged in the gas line 22 and to which the odorant is supplied as the first medium via the metering pump 26.

To supply the two-substance nozzle 36 with a second medium, a gas container 38 is also provided, in which a gas such as nitrogen is stored under pressure. Furthermore, a metering valve 40 is arranged between the gas container 38 and the two-substance nozzle 36 in order to control the volume flow of the nozzle gas flow from the gas container 38 to the two-substance nozzle 36, in particular by the control device 34 and depending on the gas volume flow in the gas line 22, which is passed through the gas meter 32 is determined.

During operation, odorant is fed from the odorant container 24 via the metering pump 26 and gas from the gas container 38 as a jet gas flow to the two-substance nozzle 36 via the metering valve 40, so that the odorant is atomized (atomized) by the jet gas flow in the gas line 22.

By using the two-substance nozzle 36, very good atomization with a small droplet size and a correspondingly large surface area of the odorant is achieved, so that the odorant can evaporate well and be mixed with the gas stream 21 in the gas line 22.

In contrast to a single-substance nozzle, such good atomization is achieved thanks to the energy provided by the nozzle gas flow even with a low throughput of odorant, so that even with a low gas volume flow through the gas line 22 and the odorant throughput set correspondingly low by the control device 32, reliable metering of the odorant is nonetheless possible can be achieved in the gas stream 21.

An evaporation body 42 can also be arranged in front of the two-substance nozzle 36 (in Fig. 2 shown in dashed lines). By atomizing the odorant with the two-substance nozzle 36, uniform wetting of the evaporation body 42 can be achieved, as a result of which good evaporation performance is achieved. The two-substance nozzle 36 can, however, also be operated without an evaporation body.

Figure 3 shows an embodiment of the device according to the invention. Corresponding components in Fig. 2 and 3 are each provided with the same reference numerals.

The device 50 differs from the device 20 in that a nozzle feed line 52 branching off from the gas line 22 is provided to provide the nozzle gas flow, through which part of the gas flow flowing through the gas line 22 is guided as a nozzle gas flow to the two-substance nozzle 36.

The branch 54 of the nozzle feed line 52 from the gas line 22 is arranged upstream of the control valve 28 in the gas line 22, that is to say on the inlet pressure side. A control valve 56 is integrated into the nozzle feed line 52 in order to reduce the gas pressure to the pressure required for the operation of the two-substance nozzle 36. The pressure in the nozzle feed line 52 downstream of the control valve 56 is preferably a few bar, for example 4 bar, above the pressure in the gas line 22 at the location of the two-substance nozzle 36.

By providing the nozzle feed line 52 with the regulating valve 56, the nozzle gas flow required to operate the two-substance nozzle 36 can be derived directly from the gas line 22, so that a separate gas source is unnecessary.

A safety shut-off valve 58 is integrated into the nozzle feed line 52 downstream of the control valve 56. The safety shut-off valve 58 is set up to limit the pressure in the nozzle feed line 52 downstream of the control valve 56 if the control valve 56 fails. In this way, a breakthrough of the admission pressure from the gas line 22 via the nozzle feed line 52 and the two-substance nozzle 36 into the region of the gas line 22 downstream of the control valve 28 can be prevented.

Furthermore, a gas preheater 60 is integrated into the nozzle feed line 52 upstream of the control valve 56, for example a passive gas preheater 60 with a vortex tube in order to heat the nozzle gas flow guided in the nozzle feed line 52. In this way, the cooling of the nozzle gas flow due to the Joule-Thomson effect due to the pressure reduction at the control valve 56 can be compensated, so that the evaporation conditions for the odorant are improved and the odorant freezes Control valve 56, the safety shut-off valve 58 or the two-substance nozzle 36 is prevented.

A gas meter 62 is installed in the gas line 22 upstream of the branch 54 of the nozzle feed line 52 in order to detect the entire gas volume flow in the gas line 22. Furthermore, a control device 34 connected to the gas meter 62 is preferably provided, which controls the metering pump 26 to adapt the odorant throughput and the control valve 56 to adapt the nozzle gas flow to the gas volume flow in the gas line 22.

Alternatively, the gas meter can also be arranged behind the junction 54 (in Figure 3 shown in dashed lines as 62 '). In this case, an additional gas meter 64 is preferably integrated into the nozzle feed line 52 in order to be able to determine the total amount of gas consumed. In this case, the control device 34 is preferably connected to the gas meter 62 ′ and possibly also to the gas meter 64.

Shut-off valves 66 are preferably also integrated into the nozzle feed line 52, with which the gas flow through the nozzle feed line 52 can be interrupted in order to switch the components arranged between the shut-off valves 66 in the gas line 22 without impairing the gas flow 21 Figure 3 the control valve 56, the safety shut-off valve 58, the gas preheater 60 and optionally the gas meter 64 to be able to maintain.

Preferably, at least one of the shut-off valves 66 can be controlled via the control device 34 and is closed by the control device 34 if the gas volume flow 21 in the gas line 22 falls below a predetermined limit value or if the gas meter 62 does not measure a gas volume flow in the gas line 22.

the Figures 4a and 4b show two examples of two-substance nozzles that are used as two-substance nozzles 36 for the in Figure 2 and 3 described devices 20, 50 can be used.

Figure 4a shows a two-component nozzle 80 based on the principle of inner mixing, in which the odorant 82 is conducted through a first channel 84 and the nozzle gas stream 86 through a second channel 88 to a mixing region 90 within the two-component nozzle 80. The meeting of the odorant 82 and the nozzle gas stream 86 in the mixing region 90 results in a misting of the odorant 82, so that a fine mist 92 of odorant emerges from the two-substance nozzle 80.

Figure 4b FIG. 10 shows a two-component nozzle 100 based on the principle of external mixing, in which the odorant 102 is passed through a first channel 104 and the nozzle gas flow 106 through a second channel 108 to a mixing region 110 outside the two-component nozzle 80. The meeting of the odorant 102 and the nozzle gas flow 106 in the mixing area 110 results in a misting of the odorant 102, so that a fine mist 112 of odorant arises in the area in front of the two-substance nozzle 80.

With the two-substance nozzles 80, 100, the odorant 82, 102 can be atomized very finely even at low throughputs, since the energy required for this is provided by the separately adjustable nozzle gas flow 86, 106. The use of a two-substance nozzle, such as the one in Figures 4a and 4b The two-substance nozzles 80, 100 shown, for odorizing a gas flow in a gas line, thus enables reliable operation over a wide gas volume flow range in the gas line.

Claims (9)

1. Device (20, 50) for odorising a gas stream (21) in a gas line (22), comprising an injecting apparatus (30) for injecting a liquid odorising agent (82, 102) into the gas stream (21) flowing through the gas line (22),

   - wherein the injecting apparatus (30) has a two-substance nozzle (36, 80, 100),

   - wherein the device (20, 50) has means for providing (38, 52) a nozzle gas stream (86, 106) for the operation of the two-substance nozzle (36, 80, 100),

   - wherein the means for providing (38, 52) the nozzle gas stream (86, 106) for the operation of the two-substance nozzle (36, 80, 100) comprise a nozzle supply line (52) branching off from the gas line (22), through which a part of the gas stream (21) flowing through the gas line (22) is supplied as the nozzle gas stream (86, 106) to the two-substance nozzle (36, 80, 100),
   characterised in that

   - a gas pre-heater (60) is integrated into the nozzle supply line (52), in particular with a vortex tube.
2. Device according to claim 1,
   characterised in that the device (20, 50) further has means for storing (24) a liquid odorising agent (82, 102).
3. Device according to claim 1 or 2,
   characterised in that the branching (54) of the nozzle supply line (52) is arranged upstream in the flow direction and the two-substance nozzle (36, 80, 100) is arranged downstream in the flow direction of a regulating valve (28) for reducing the pressure in the gas line (22).
4. Device according to any one of claims 1 to 3,
   characterised in that a regulating valve (56) is integrated into the gas supply line (52).
5. Device according to any one of claims 1 to 4,
   characterised in that a safety shut-off valve (58) is integrated into the gas supply line (52).
6. Device according to any one of claims 1 to 5,
   characterised in that the branching (54) of the nozzle supply line (52) is arranged downstream of a gas meter (62).
7. Device according to any one of claims 1 to 6,
   characterised in that shut-off valves (66) are integrated into the nozzle supply line (52) in order to be able to shut off a region of the nozzle supply line (52).
8. Method for odorising a gas stream (21) in a gas line (22),

   - in which a liquid odorising agent (82, 102) is injected by means of a two-substance nozzle (36, 80,100) into the gas stream (21) flowing through the gas line (22),

   - wherein the two-substance nozzle (36, 80, 100) is operated with the liquid odorising agent (82, 102) and with a nozzle gas stream (86, 106),

   - wherein the nozzle gas stream (86, 106) is branched off from the gas stream (21) flowing in the gas line (22),

   characterised in that
   heat is supplied to the nozzle gas stream (86, 106) by a gas pre-heater (60) integrated into the nozzle supply line (52).
9. Method according to claim 8,
   characterised in that the nozzle gas stream (86, 106) is branched off upstream of a pressure reduction of the gas stream (21) flowing in the gas line (22).

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