DE9218419U1 - Device for taking soil pore gas samples - Google Patents

Description

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Device for taking soil pore gas samples

The invention relates to a device for taking soil pore gas samples by means of a probe inserted into the soil, through which the gas is sucked out by means of a pump in the absence of air, with a sampling area for sucked out gas arranged upstream of the pump and a measuring station arranged behind the pump, in particular for checking the sucked out gas prior to sampling.

Soil pore gas investigations are of interest when it comes to exploring areas where contamination has occurred by volatile chlorinated hydrocarbons or other volatile aromatic hydrocarbons. The same applies to the investigation of embankments and landfills. Pollutants are determined in soil pore gas samples taken using suitable gas chromatography methods. Sampling can be carried out either by direct sampling, i.e. by sucking out the base and filling it into containers, or by sorption onto appropriate sorbents. Sorption onto a sorbent has the advantage that, due to the large volume of gas that is passed through the sorbent, correspondingly lower detection limits are achieved during analysis.

The composition of the soil pore gas is influenced by biological processes that take place in the pore space of the soil and therefore differs more or less strongly from that of the atmospheric air depending on the type and extent of these processes. The deviations in the composition consist primarily of a decrease in the O2 content and an increase in the CO2 content. During anaerobic biological decomposition processes, methane and hydrogen sulphide are also formed. The oxygen content in the

Soil air is often lower than in the atmosphere because the amount of O2 used up by all kinds of life processes in the soil is only relatively slowly replaced by the atmospheric air. The oxygen content in soil air is therefore lower the more intensive the root growth and the life activity of the edaphon. It is therefore lower deeper in the soil than near the soil surface, lower in fine-grained soils than in coarse-grained soils, lower in moist soils than in dry soils, lower in seasons of lively biological activity than in seasons of sluggish biological activity. The supply of molecular oxygen to soil air occurs exclusively from the atmospheric air and therefore through the soil surface. The CO2 content of the soil pore gas in soils is generally higher than in the atmosphere because CO2 is produced by the respiration of the roots and the edaphon. It is therefore higher in deeper layers of the soil than near the soil surface, higher in fine-grained soils than in coarse-grained soils, higher in wet soils than in dry soils, higher in seasons with lively biological activity in the soil than in seasons with sluggish soil life. When the molecular oxygen in the soil is completely used up by biological processes, but the life of anaerobic organisms continues, some other gases are produced when organic compounds are broken down, especially CH4 and H2S. The processes that take place are particularly pronounced when there is water saturation and are therefore most pronounced in semi-terrestrial or hydromorphic soils, especially in subhydric soils. They also lead to the formation of CO2, but low-molecular organic compounds with low volatility are also produced as intermediate stages, such as acetic, lactic or butyric acid, which are only broken down in further steps to form methane. Small amounts of H2S are also produced.

In a device for obtaining soil pore gas samples, as described in DE 36 37 952, a gas sample is taken using an injection syringe that can be attached to a tapping point on the probe as soon as a CO2 maximum has developed in the area of the tapping point, which is determined in a measuring station through which the extracted soil pore gas initially flows. In the majority of cases, however, the CO2 maximum alone is no guarantee in connection with soil tests that at the moment of sampling there is soil pore gas at the tapping point that corresponds to the soil pore gas in the subsoil to be examined. The method of sampling itself certainly does not rule out falsification of the sample.

Based on this state of the art, the invention is based on the need for a device that ensures that the sample taken authentically represents the actual qualitative and quantitative composition of the soil pore gas in the subsurface and, on the other hand, enables a detailed analysis of the sample taken.

The object is achieved according to the invention with a generic device, the extraction area of which is formed by a branch of the suction line extending from the probe, the branch lines of which are connected to a changeover tap upstream of the pump, with a receptacle for sample tubes formed in one of the branch lines, and the measuring station has a plurality of measuring systems for different characteristic components of the extracted gas that can be jointly supplied with extracted gas by the pump.

Determining the time of sampling after reaching the equilibrium between the characteristic components of the soil pore gas ensures that the sample taken corresponds to the composition of the soil pore gas in the subsoil.

Embodiments of the device according to the invention result from subclaims 2 to 8. A probe with a replaceable core eliminates falsifications caused by residues in the probe from previous sampling.

The invention is explained in more detail in the drawing.

Figure 1 shows the device according to the invention
illustrative flow chart throughout
schematic representation

Figure 2 shows a probe designed according to the invention

The probe shown schematically in Figure 1, inserted in the direction of arrow A into the ground B, such as a landfill or contaminated subsoil, is designated 11. A line 121, 123 leads from the probe 11 to the filling station 13 with the conveniently adjustable sample tube holder 131, 131', to which sample tubes 132 collecting gas extracted via the probe 11 are assigned for sampling (double arrow C in Fig. 1).

A shut-off device 14 is inserted into the line 121. Before the filling station 13, the line 121 opens into the connection 1 of a change-over valve 16, at the connection 2 of which there is a further access line 122 and at the connection 3 of which there is a

Branch lines 123', 123". This changeover valve 16 normally assumes the switch position 1-3. In the first branch line 123' is the filling station 13 for the sample tubes 132 that can be inserted into the sample tube holder 131, 131'. The second branch line 123" is a bypass line. Both lines 123' and 123" run together again in the changeover valve 17, at whose outlet connection 3 the continuing line 124 is located. In the switch position 1-3 of the changeover valve 17, the line branch 123' is continuous with the filling station 13, in the switch position 1-3 the bypass line 123". In the continuing line 124 there is a feed pump 18 and a flow meter 19 with an adjustable throttle 21 upstream. Behind the flow meter 19, the line 124 opens into the connection 1 of a changeover valve 22, at the connection 3 of which the line 126 is located, which leads via branch lines 126', 126", 126'" to the gas component measuring systems 261, 261', 261" of the measuring station 26. At the remaining connections 2 and 2' of the changeover valve 22 there is a discharge line 128 on the one hand and a supply line 129 on the other. The measuring systems 26, 26", 26" supplied by the branch lines 126' and 126", 126'' are each preceded by a flow meter 23 with an associated adjustable throttle 24. Of the measuring systems 26, 26", 26" lead to lines 127, 127", 127"'. A further branch line 126 ^IV leading from line 126 passes via a flow meter with a throttle upstream thereof directly into a line 127 ^{1 v} .

The measuring systems 261, 261', 261" are commercially available sensors that respond to specific components or mixtures of components of the soil gas and, in conjunction with computers, determine the respective volume percentages.

which are displayed, in the present case a system 261 responding to CHU, a system 261' responding to CO2 and a system 261" responding to the mixture CEU, O2 and H2S. If flow meters with an adjustable throttle are provided, these are adjusted, i.e. set to a specific flow rate per unit of time and readjusted if necessary, for example if the density of the gas to be extracted is different. The sample tubes 132 contain sorbents for the various gas components or component mixtures, in the special case three sample tubes with different sorbents are used for one and the same test, whereby one and the same test can include several runs.

To test, the probe 11 is first driven into the ground B (arrow A in Fig. 1). A sample tube 132 is then clamped into the filling station 13 on the sample container 131, 131'. The changeover valve 17 is then moved to the switch position 2-3 and the pump 18 is then switched on. If the flow rate display in the flow rate indicator 19 then returns to zero after a short time, this is an indication that the upstream line is tight, in particular that the sample tube 132 is properly clamped. Then, first of all, the so-called flushing of the measuring station 26 takes place. For this purpose, the shut-off device 14 is opened, the change-over valve 22 is moved to the switch position 1-3 and the pump 18 is switched on again. Soil pore gas sucked in via the probe 11 thereby reaches the measuring systems 261, 261', 261" of the measuring station 26 via the branch lines 126', 126", 126'", bypassing the filling station 13, especially the sample tube 132 clamped into the filling station 13, which it leaves via the outlet lines 127', 127", 127"'. Excess

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The gas is discharged via the branch line 126 ^IV and the discharge line 127 ^IV . As the flushing progresses, a decrease in the oxygen content and a related increase in the CO2, CHU or H2S content can be read on the measuring systems 261, 261', 261". If a stable equilibrium has been established between these components, this is an indication that pure soil pore gas is present. Sampling can now take place. For this purpose, the changeover valve 17 is moved to the switch position 1-3. With the main branch line 123" dropped, the soil pore gas is now sucked via the bypass branch line 123 through the sample tube 132 clamped into the sample holder 13, whereby the respective gas component from the gas flowing through is adsorbed by the sorbent in the sample tube 132. The residual gas leaving the sample tube 132 is either discharged via the measuring station 26 itself or, if the switch valve 22 is in the switch position 1-2, via the discharge line 128. If the residual gas is discharged via the discharge line 128, the measuring station 26 can be simultaneously flushed by flushing gas, usually ambient air, entering the measuring station 26 through the supply line 129 via the connections 2'-3. For this purpose, the measuring systems 261, 261', 261" are assigned independent pumps. A renewed flushing of the measuring station 26 immediately after the sampling provides information about whether the previously determined equilibrium between the components of the soil pore gas is still present. If this is not the case, the previous sampling must be discarded.

All process steps are recorded taking into account the respective time period in order to enable identical reproductions. Controlling the process sequence proves to be useful, especially in the state

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dium for determining the stable equilibrium between the gas components and at the sampling stage via a timer.

Preferably, sample tubes 132 containing gas component-specific sorbents are used as sample containers. This does not exclude the additional filling of extracted soil pore gas into gas bags if necessary. In this case, the measuring station directly provides the quantitative proportions of CO2, CH4 and O2 in the extracted soil pore gas if the amount of H2 S is negligible. From the values determined, the nitrogen content can then also be determined using the formula

Σ of the gas components in Vol.% =
Conc.CH4 + Conc.02 + Conc. CO2 + Conc.N2

calculated. The sampling system can of course _also be connected to stationary probes, so-called gauges. The connection 2 of the change-over valve 16 opens up the possibility of flushing the filling station 13 with ambient air.

A probe II ¹ (Fig. 2) with a replaceable core 112, namely a hose made of gas-tight material, such as Teflon, which extends between the gas inlet 111 at the base of the probe and the connection of the line 121 leading to the sampling system in the area of the head of the probe, ensures that residues from the previous measurement do not falsify the measurement results of the subsequent measurement. The comparatively small cross-section of the replaceable core 112 also has the advantage of a significantly smaller dead volume in the probe area. The

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The lines 121 and 123 leading to the sample tube holder 13 are expediently interchangeable in order to reduce the so-called memory effect.

Claims (8)

Protection claims 1. Device for taking soil pore gas samples by means of a probe inserted into the soil, through which the gas is sucked out by means of a pump in the absence of air, with a sampling area for sucked out gas upstream of the pump and a measuring station arranged behind the pump, in particular for checking the sucked out gas prior to sampling, characterized in that the sampling area (13) is formed by a branch of the suction line (121) extending from the probe (11), the branch lines (123', 123") of which are connected to a changeover tap (17) upstream of the pump (18), with a receptacle (13) formed in one of the branch lines for sample tubes (132), and the measuring station (26) has a plurality of measuring systems (261, 261', 261") which can be jointly supplied with sucked out gas by the pump (18) for different characteristic components of the sucked out gas. gas. 2. Device according to claim 1, characterized in that flow meters (19, 23) are inserted both into the main line (124) supplying the measuring station (26) and into the branch lines (126", 126", 126"') extending from the main line (126) supplying the individual measuring systems (261, 261', 261 " ). 3. Device according to claim 2, characterized by adjustable throttles (21, 24) arranged upstream of the flow meters (19, 23). 2 - 4. Device according to one of claims 1 to 3, characterized by a changeover tap (16) with an access (122) for flushing gas, which is arranged upstream of the branch forming the removal area (13). 5. Device according to one of claims 1 to 4, characterized by a changeover tap (22) upstream of the branch lines (126', 126", 126"') leading to the various measuring systems of the measuring station (26) with an outlet (128) to the outside. 6. Device according to one of claims 1 to 4, characterized by a changeover tap (22) upstream of the branch lines (126', 126", 126"') leading to the various measuring systems, with an outlet (128) to the outside and with an inlet (129) for purge gas. 7. Device according to one of claims 1 to 6, characterized by a probe (11) that can be inserted into the ground and has a replaceable core (112) extending between the gas inlet (111) at the base of the probe (11) and the connection of the line (121) leading to the filling station (13) at the head of the probe. 8. Device according to claim 7, characterized in that the core (112) consists of flexible material.