EP1537400A1

EP1537400A1 - Method and device for taking indoor air samples

Info

Publication number: EP1537400A1
Application number: EP03732350A
Authority: EP
Inventors: Albrecht Vogel; Peter Krippner; Manfred Wetzko; Christian J. Schmidt; Antonio Ruzzu; Rolf Merte; Jan Czyzewski
Original assignee: ABB Patent GmbH
Current assignee: ABB Patent GmbH
Priority date: 2002-05-10
Filing date: 2003-05-12
Publication date: 2005-06-08
Also published as: WO2003095983A1

Abstract

The invention relates to a method and device for taking indoor air samples. The aim of the invention is, while differing from the provisions of the prior art, to not only analyze indoor air but also to make it possible to promptly influence the same or at least to able to promptly determine questionable concentrations of indoor air components in order to make appropriate prompt provisions possible. To this end, the indoor air sampling and the analysis are carried out in prompt and proximal succession.

Description

Method and device for taking room air samples

description

The invention relates to a method and a device for sampling indoor air samples according to the preamble of claims 1 and 7. The invention thus relates to the field of air quality monitoring in closed rooms.

The state of the art for this is to take the air samples from closed rooms and send them to a laboratory in a separate analysis process. For this purpose, stationary or transportable air sample meters are used, which are based, for example, on the principle of centrifugal separation, gas washing or membrane filter technology.

When examining air samples from closed rooms, so-called patogenic components are also switched off within the room air, and this requires a corresponding preparation of the air samples.

Thus, the obvious disadvantage of the conventional method and the conventional procedure is that an apparatus separation between sampling and analysis is provided. In addition, it follows that known systems are also complex and structurally large and even require the chronological separation between sampling and analysis.

On the other hand, systems of this known type can only determine indoor air quality, but they cannot be regulated or adjusted in a timely manner.

The invention is therefore based on the object, in deviation from the requirements of the prior art, not only to analyze the ambient air, but also promptly

BESTÄTIGÜNGSKOPIE To be able to influence them, or at least to be able to determine timely questionable concentrations of indoor air components in order to enable suitable timely measures.

The object is achieved in a method of the generic type according to the invention by the characterizing features of claim 1.

A further advantageous embodiment of the method according to the invention is specified in the dependent claims 2 to 6.

With regard to a device of the generic type, the object is achieved according to the invention by the characterizing features of claim 7.

Further advantageous refinements of the devices according to the invention are specified in the remaining dependent claims.

The basic idea according to the invention, in a manner according to the method and also according to the device, is that the room air sampling and the analysis are carried out immediately and in real time.

On the one hand, this has the advantage that there is a timely and local result between the current indoor air quality and the analysis as such.

In addition, this opens up the possibility that the location and timely sampling and sample analysis can now be used to directly influence the climate and / or circulating air controls of buildings. In this way, direct and timely influence can be exerted on the room air parameters.

Furthermore, it is advantageously configured that threshold values can be set for this, on the basis of which appropriate suitable measures can then be generated. A direct influence can be created by setting threshold values for certain indoor air components. ^• 3 - May 12, 2003

In a further advantageous embodiment it is stated that in the method according to the invention the sensitivity to different gas components and / or aerosols can be set. In this way, different gas components and / or aerosols that are of interest and are decisive for the indoor air quality can be used.

In the case of the corresponding adjustment to the relevant gas and / or aerosol components, it is also advantageously configured that they are enriched in a system by enrichment according to the gas scrubber principle and then analyzed. This gives a correspondingly higher level of traceability.

In a further advantageous embodiment it is stated that this crediting process can also be carried out by spray concentration.

With regard to a device of the generic type, the essence of the invention is to integrate the room air sampling means and the analysis means in an overall structural unit interconnected locally.

This enables the method according to the invention to be carried out in a simple manner. Compared to the prior art, the main difference now is that there is no longer a structural separation between sampling and analysis, but these are structurally combined.

The corresponding units for this can be made compact, especially when micromechanical line and analysis systems are used.

Either so-called gas scrubber or micro concentrators or micro gas scrubbers with an open or closed circuit and spray concentrators with a closed circuit can be used for the enrichment. Molecular filter systems or multi-stage filter systems can also be used. The invention is illustrated in the drawing and described in more detail below.

It shows:

Fig. 1: Modular structure of the microsensor system.

Fig. 2: Modular sampling unit.

Fig. 3: microconcentrator.

Fig. 4: Micro gas scrubber module.

Fig. 5: Microconcentrator with closed liquid flow.

Fig. 6: spray concentrator.

Fig. 7: spray concentrator with closed liquid flow.

Fig. 8: Micromixer.

Fig. 9: Molecular filter system.

Fig. 10: Two-stage filter system.

FIG. 1 shows the idea on which the invention is based, the sampling and

Realize analysis unit with the help of microsystem technology as a modular microsystem. In a first stage, module 1, the gas to be examined, for example ambient air, is brought into contact with the solvent, for example water, for the purpose of dissolving the foreign substances. Via a microchannel system, module 2, this solution is fed to a second unit, module 3, where it is analyzed with the help of a test specific to the respective foreign substance.

The evaluation takes place via a microprocessor, module 4, and is displayed via a defined interface, module 5. The analysis result can be displayed either in proportion to the actual concentration or as Alarm function, i.e. displaying a signal when a threshold value is exceeded.

The modular structure enables individual functional units to be exchanged. In particular, the analysis unit can be used to renew or to detect others

Foreign substances are exchanged.

FIG. 2 shows that by implementing the arrangement in microsystem technology, module 1, the sampling and solution unit can again be produced as a compact, modular system. Due to the modular structure, critical components, such as the actual unit for solving the foreign substances, can also be provided as a replacement part and can be exchanged at certain replacement intervals or after the alarm has been triggered by the control electronics. The sampling unit is shown in the other figures. Figure 3 shows a possibility of building a micro-concentrator based on the principle of gas scrubbing.

The basic arrangement provides for the gas to be examined to flow through a liquid container. The amount dissolved is determined via a flow measurement and the solubility of the substances to be examined.

Figure 2 shows a micro gas scrubber unit consisting of a multi-level structure with a coupled gas and liquid guide. The liquid is fed into a micromechanically produced cavity via valves. The gas is pumped into the liquid via a plate with a large number of microchannels. By dividing the gas flow into a large number of small outlet openings, a very large interface between the two media is obtained with a high gas throughput.

Figure 4 shows the possibility of reducing the position dependency due to the liquid filling. By reducing the hole size in the gas supply, the gas line can be prevented from running full due to the lateral arrangement of the gas channels. Depending on the liquid, this is due to an opening diameter in the

Micrometef range possible. The surface energy of the three interfaces is decisive for the necessary channel size. Alternatively, a gas-permeable membrane can also be used in such a microsystem. According to FIG. 5, the reproducibility of such a microconcentrator can be increased by operating with a closed gas circuit. Here, a defined amount of gas is enclosed in a recipient V1. This is then passed through the liquid several times in a closed circuit by means of a pump. This allows the percentage of solutes to reach each

Solubility product are gradually increased. With a very low concentration of the substances to be dissolved in the gas, this cycle can also be carried out several times with the volume V1 being refilled. Here, the liquid filling V2 remains during the cycle repetitions in order to achieve a concentration in the solution.

A further possibility of achieving a forced solution of the foreign substances is to spray the solvent liquid by means of a nozzle in a recipient filled with the gas to be examined according to FIG. 6. Due to the very large total surface area and thus the interface of the liquid drops, a large proportion of the foreign substances in the gas are dissolved. The distributed liquid is condensed again by cooling the walls of the recipient, pumped out and can be used for further analysis.

Figure 7 shows another example. By repeating the process, that is

If the solution is atomized and condensed, the proportions of gas-borne foreign matter still present in the recipient can be increasingly dissolved and the substances can be concentrated in the solution. This can be done both cyclically and continuously. For this purpose, a closed circuit is created via a second pump. The solvent is no longer injected directly into the nozzles, but rather injected into the circuit at the beginning. After running through the required number of cycles or time, the gas consumed in the above sense is released and the recipient is refilled.

Figure 8 shows that a large interface between the gas in the solvent can also be achieved by swirling in a mixer unit. The gas and liquid supply are each divided into many small channels and then merged again. The mixing ratio is set by the line cross-sections and different flow velocities. The foreign substances are dissolved out on a subsequent mixing section the gas into the solvent. The exhaust gas can then be withdrawn from the solution in a degasser by means of a pump.

FIG. 9 shows how foreign substances contained in the gas to be examined are filtered out and solved by finally rinsing the filter. For this purpose, the gas is passed through a filter. The amount of foreign matter collected is determined by the volume flow and the filter is then rinsed with a suitable solvent through a fluid circuit connected in parallel.

Figure 10 shows a two-stage filter screen. The solvent flows through both here

Filters, whereby particle-bound substances are also washed out and made accessible for further analysis.

From the modularity of the individual elements and above all the procedure according to the invention that the room air sampling and the analysis are immediately connected in real time and location, a compact and coherent design results.

Claims

claims:

1. A method for taking room air samples, characterized in that the room air sampling and the analysis are connected immediately in time and place.

2. The method according to claim 1, characterized in that for this threshold values can be set, on the basis of which suitable measures can then be generated.

3. The method according to claim 1 or, characterized in that the sensitivity to different gas components and / or aerosols is adjustable.

4. The method according to any one of the preceding claims, characterized in that the gas components in question by enrichment after

The gas scrubber principle can be enriched in a system and subsequently analyzed.

5. The method according to any one of the preceding claims, characterized in that the gas components in question takes place by enrichment by spray concentration and is subsequently analyzed.

6. Device for taking and analyzing room air samples, characterized in that the means for taking room air samples and the analysis means are arranged in an integrated manner in an integrated overall unit.

7. Device according to claim 6, characterized in that the device is integrated into an entire air conditioning system.

8. Device according to one of claims 6 or 7, characterized in that threshold values can be set, on the basis of which suitable measures can then be generated acting on the air conditioning device.

9. Device according to one of the preceding claims, characterized in that the sensitivity to different gas components and / or aerosols is adjustable.

10. Device according to one of the preceding claims, characterized in that an enrichment of the gas component in question takes place with the aid of an integrated micro gas scrubber.

11. Device according to one of the preceding claims, characterized in that a molecular filter is integrated to cushion solid components.