WO2007022895A2 - Measuring device for optical determination of toxic gas concentration by transmission - Google Patents

Abstract

The aim of the invention is to produce a measuring device by means of which the concentration of a toxic gas can be rapidly and simply determined. According to the invention, said aim is achieved by means of a measuring device for optical determination of the concentration of at least one toxic gas by transmission, comprising a measuring cell which is not transparent to light, with a housing in which a tubular at least partly transparent detection means, at least partly provided on the inner wall thereof with a transparent coating of a given layer thickness made from at least one polymeric material with at least one indicator substance immobilised therein, further comprising a pump or suction device arranged before or after the detection means, which pumps a toxic gas stream through the detection means and at least one light source and at least one receiver means arranged to one and/or more sides of the detection means, by means of which an absorption change for the indicator substance is measured by transmission as a function of time. The receiver means may be connected to an analysis unit.

Description

 Measuring device for the optical determination of a noxious gas concentration in transmission

description

The present invention relates to a measuring device for the optical determination of the concentration of at least one noxious gas in transmission, as well as a corresponding method. In the context of the present invention, noxious gas refers to a gaseous and / or vaporous component of a gas mixture.

The detection of noxious gases is particularly important from the environmental point of view, but also from the point of view of job security of great importance. Known from the prior art are the so-called test tubes, for example, the company Dräger, Lübeck, which are filled with an impregnated with an indicator substance silica gel. Flows through a noxious gas, for which the recorded in the silica gel indicator substance is sensitive, the test tube, as a result of the reaction with the indicator substance forms a gradually colored zone whose intensity and time course is related to the concentration of the gas to be detected. This color zone is visually evaluated according to its progress in the detector tube, and the gas concentration is read from a scale printed on the tube.

A disadvantage of this known prior art is that, due to the visual evaluation of the test tube, there is a large reading inaccuracy, especially in the presence of diffuse ink zone boundaries. Another major disadvantage is that the known test tubes have a relatively low sensitivity, or the measurement time must be relatively long, since a visually perceptible color change must be a high mole conversion.

The object of the present invention is therefore to provide a measuring device with which the concentration of noxious gases can be quickly and accurately determined in a simple manner

Way can be determined.

This object is achieved by a measuring device for optically determining the concentration of at least one noxious gas in transmission, comprising a light-transmissive measuring cell with a receptacle in which a tube-shaped, at least partially transparent, preferably optically transparent detection means which On its inner wall at least partially a translucent, preferably optically transparent charge having a predetermined layer thickness of at least one polymeric material with an immobilized in this indicator substance is arranged, further comprising a detection means upstream or downstream pumping or suction device, which directs a noxious gas flow through the detection means, as well as at least one light source and at least one receiver means, which are arranged on one and / or more sides of the detection means, by means of which in transmission an absorption change of the indicator substance as a function of time is measured, wherein the receiver means with a Evaluation unit is connectable. The measurement device according to the invention has the great advantage that reproducible measurement results can be obtained very quickly by the pumping or suction device via the detection means, and the pollutant gas concentration can be determined by measurement in transmission with high accuracy. The carrier means of the detection means is preferably arranged at least partially translucent, more preferably made of a transparent and clear, in particular gas-impermeable material, for example of glass and / or suitable plastics. The measuring device according to the invention is not spatially sensitive with regard to the positioning of the detection means, since just in contrast to the prior art, no color zone course is measured.

The polymeric material applied at least partly on the inner wall for the layer to be applied to the detection means is preferably selected from a group comprising polysiloxanes, polycarbonates, polyacrylates, polymethacrylates, perfluoropolyethers, polystyrenes, polyolefins, polyisocyanates, polyols, polyamines, polyamides, polyesters, Polyvinyls, polyimines, polyglycols, polyphenylene oxides, polysulfones and / or polyethersulfones and their derivatives. The materials to be used according to the invention can also be used as copolymers, preferably as block copolymers. Silicone-polycarbonate block copolymers are particularly preferred here. The coating of the detection agent can contain both pure polymers and polymer mixtures. Likewise, a synthesis of the polymeric material on the detection means of precursor substances is possible with simultaneous or subsequent immobilization of the indicator reagent. It can also be provided that the coating of the detection means consists of several layers, these layers each having different indicator substances. However, it can also be provided that a plurality of different indicator substances are accommodated in a single layer. The indicator substance is preferably a color indicator, in particular homogeneously incorporated in the polymeric material, which is preferably soluble in the polymeric material, and more preferably selected from a group comprising diphenylamine, indigo, o-tolidine, phenylenediamine and / or bromophenol blue or theirs Derivatives, with particular preference being given to diphenylamine, 4,4'-dinonoxy-7,7'-dimethoxyindigo, o-tolidine, N, N'-diphenyl-1,4-phenylenediamine and / or bromophenol blue.

The indicator substance is immobilized in the polymeric material. The immobilization can be carried out in particular via hydrogen bonds. Therefore, as polymeric materials in the context of the present invention, those polymers are preferred which have chemical groups for the formation of hydrogen bonds. As such chemical groups, both CO groups, which act as acceptors of hydrogen atoms in the formation of a hydrogen bond, as well as OH, NH, NH ₂ and SH groups, which act as donors of hydrogen atoms, come into question. In this case, the preferred polymeric material preferably in the layer formed has a high permeability for the component to be detected of the gas mixture, ie the / the pollutant gases (s) on. However, it is also possible that the immobilization of the indicator substance in the polymeric material takes place via the dipole-dipole interactions, Van der Waals interactions or even via covalent bonds.

The detection means is produced by coating a carrier with a polymeric material and the at least one indicator substance to be immobilized in it. In this case, the application of the coating can be carried out by any known method, for example by brushing or brushing, atomizing, dip-coating, spraying or molding. As a result, the production of the detection means can be carried out inexpensively. Preferably, the coating of the detection means has a total thickness in a range from about 0.1 μm to about 1 mm, the layer thickness is preferably in a range from about 0.1 μm to about 50 μm, even more preferably in a range from about 1 μm to about 20 μm. The choice of the thickness of the layer of the polymeric material with the indicator substance immobilized in this depends inter alia also on the latter, in particular with what amount of the indicator substance the polymeric material can be loaded. Preferably, the amount of the indicator substance in the polymeric material is in a range from about 0.1% by weight to about 120% by weight, based on the particular polymeric material used. The amount of indicator substance incorporated in the polymeric material is dependent on the one hand on the chemical compatibility of the polymeric material with the respective indicator substance, and on the other hand of the layer thickness of the polymeric material used. By increasing the amount of indicator substance in the polymeric material, the sensitivity can be significantly increased. The indicator substance is preferably applied together with the polymeric material on the carrier of the detection means. By applying a coating on the inner wall of the detection means, only a very small volume element with the indicator substance is offered to the through-flowing harmful gas, whereby a rapid reaction is made possible. The noxious gas preferably flows essentially by convection through the detection means. As a result, the measurement of the noxious gas can be done very quickly.

The measuring device according to the invention has a tube-shaped detection means. In this case, the inner wall of the tube-shaped detection means is at least partially, ie provided in the region of the measuring beam, with the coating. The gas-impermeable tube serves as a carrier for the coating. Preferably, in this case, the coating of the carrier with a polymeric material and at least one immobilized in this indicator substance by dip coating. Subsequently, the polymeric layer deposited on the outer wall of the tube is then simply removed by means of a solvent such as acetone, or the tube is externally protected by a removable medium, eg, Tesafilm, during the dip-coating process. As tubes or carrier means, preference is given to using those made of glass, in particular those made of borosilicate glass. The design of the detection means in the form of a tube has the great advantage that on the one hand, the tube before insertion into the measuring device gas-tight by means of, for example, films which are arranged on both ends of the detection tube, can be closed by methods according to the prior art. Contamination of the detection means before use in the measuring device according to the invention is thus reliably avoided. The films are preferably designed such that they can be opened easily by piercing. Appropriate tools for this purpose are provided in the receptacle of the measuring cell, in which case sealing means which are accommodated in a groove and which act sealingly against the ends of the tube-shaped detection means. As a result, a change in the volume flow caused by the pump is also reliably prevented by lateral outflow of gas. Instead of a groove, however, any other receptacle can be provided which is suitable for enabling a sealing means for sealing the detection means within the measuring cell of the measuring device according to the invention. The sealant is preferably formed as a sealing ring, which may also be formed profiled. In a further preferred embodiment of the measuring device according to the invention, the at least one receiver means is designed as a photodiode, phototransistor and / or photoresistor. Preferably, the receiver means is designed kleinbauend. This makes it possible, in combination with a correspondingly small-sized light source, which is preferably designed as an LED, even relatively small built detection means, in particular in the form of a tube to use, so here over the entire light channel between the light source and receiver means in leadership a constant volumetric flow of the gas by means of the pumping or suction device can be a uniform and, above all, rapid determination of the harmful gas concentration. However, it is also possible to use as receiving means any other light detectors which are known from the prior art.

The measuring device according to the invention preferably has a pumping or suction device, which sucks the noxious gas at a constant, preferably high volume flow in a range of preferably about 100 to 10,000 ml / min, more preferably about 1000 to 2000 ml / min. The noxious gas is thereby guided uniformly over the sensitive layer of the detection means. It is preferably provided that the pumping or suction device is subsequently arranged the detection means in the measuring device according to the invention, wherein the pumping or suction device can also be arranged within the measuring cell with sufficient miniaturization. As a result, the noxious gas stream is uniformly sucked over the sensitive layer of the detection means. It may be provided a conventional known from the prior art pumping or suction device, preferably a suction device.

More preferably, the measuring device according to the invention has a humidity and / or temperature and / or mass flow sensor. This can be arranged upstream or downstream of the detection means, preferably downstream of the detection means, but still in front of the pumping or suction device. By correlation with the measured humidity and / or temperature and / or the mass flow, the noxious gas concentration can be determined very accurately. The humidity and / or temperature and / or mass flow sensor is preferably connected to the same evaluation unit as the measuring cell, wherein in addition the pumping device can also be connected to the evaluation unit. The evaluation unit advantageously comprises an AD converter for digitizing the measurement signal, and advantageously a PC interface for controlling and evaluating the Measurement data by means of a software or a microcontroller for PC-independent operation on site.

In a preferred embodiment of the present invention, a wall of the receptacle of the measuring cell is at least partially provided with a reflective surface. This makes it possible to achieve an increased sensitivity of the measuring device according to the invention, since the light beam is guided several times through the coating of the detection means by the reflection within the recording. In this case, the light source and the receiver means can be arranged on one side, but optionally also on opposite sides of the detection means, for example. An increase in the sensitivity of the measuring device according to the invention can also be achieved by providing, for example, a plurality of light sources and receiver means. Under certain circumstances, light sources with different wavelengths can be used. Preferably, the determination of the noxious gas concentration in the UWVIS and / or nIR range, so that corresponding light sources can be used. The wavelength of the corresponding light sources is matched to the indicator substance used. Therefore, in order to achieve the greatest possible flexibility of the measuring device according to the invention, therefore, either a plurality of light sources of particular wavelength are selected with regard to the indicator substance or the pollutant gas concentration to be determined, but it is also possible to select a light source which operates over a broad wavelength range.

The present invention further relates to a detection tube and a method for the optical determination of at least one noxious gas in transmission, wherein at a constant volume flow, a noxious gas stream is passed through a arranged in a measuring cell detection means, formed in the form of a tube, which is a coating of at least one polymeric material in which at least one indicator substance is immobilized, wherein at least one light beam is passed through the detection means, and wherein at least in a partial area, the speed of the measurable transmission or voltage change, from which an absorption change of the indicator substance can be determined, and / or the The speed of the absorption change runs approximately linearly with the harmful gas concentration to be measured. This advantageously makes it possible to carry out very precise determinations of harmful gas concentrations. In particular, the calibration of the measuring device according to the invention is considerably simplified, being determined at different gas concentrations and temperatures as well as moisture contents and / or mass flows Measurement data can be implemented by means of software in the evaluation, so that the determination of unknown concentrations of harmful gas is simply made possible here. Harmful gases which are preferably determined by means of the measuring device and detection tube according to the invention and the method according to the invention are nitrogen oxides, in particular nitrogen dioxide, sulfur dioxide, ozone, chlorine, ammonia and / or hydrogen sulphide.

Preferably, according to the method according to the invention, the light beam is guided at least twice through the detection means. If the detection means has a tubular shape with a coating of a polymeric material with at least one indicator substance immobilized on the inner wall thereof, the light beam is guided through the coating at least twice by the transmission measurement, which in addition to the coating caused by the curvature of the Coating caused enlargement of the irradiated sensitive surface in addition to an increase in the sensitivity of the inventive method contributes. If, in addition, the light beam is repeatedly guided through the particular tube-shaped detection means by a reflective layer applied at least partially on a wall of the receptacle, a considerable increase in the sensitivity of the method according to the invention is achieved.

These and other advantages of the present invention will be explained in more detail with reference to the following figures. Show it:

1 shows a perspective view of a detection means according to the invention for a measuring device according to the invention;

2 shows a schematic representation of the detection means together with the gas-tight foils which can be applied at the ends thereof;

3 shows a schematic representation of the measuring device according to the invention;

4 shows a sectional view through a measuring cell of the measuring device according to the invention in a plane passing through the light source and the receiver means;

5 shows a cross section through the measuring cell of FIG. 4 in a through the

Light source and the receiver means leading level; 6 shows a second embodiment of a measuring cell; 7 shows a third embodiment of a measuring cell with a reflective

Wall of the recording of the detection means;

8 shows a fourth embodiment of the measuring cell using a light guide or forming a light entry shaft; 9 shows a plot of the measured voltage change with the measuring cell according to the invention against the measuring time in the determination of nitrogen dioxide at a concentration of 2 ppm according to Example 1;

10 shows a plot according to FIG. 9 at a nitrogen dioxide concentration of

25 ppb according to Example 1; and FIG. 11 shows a plot of the determined nitrogen dioxide concentration against the

Speed of voltage change according to Example 1.

It should first be noted that the features disclosed in the figures are not limited to the individual concrete embodiments shown there. Rather, the features specified in each case in the description, including the description of the figures and the drawings, can each be combined with each other for further development. Incidentally, in the present figures, the same features are denoted by the same reference numerals.

FIG. 1 shows in a perspective view a total of a detection means designated by the reference numeral 16, which has a tube-shaped carrier means 17 with a coating 18 applied to the inner wall 28 thereof. In the interior of the detection means 16, a flow channel 40 is provided. Through this flow channel 40, the noxious gas is passed.

Fig. 2 shows for clarity the construction of the detection tube 16 in detail, 16 here gas-impermeable films 32.1 and 32.2 are arranged on the ends 30.1 and 30.2 of the detection tube. A detection tube 16 designed in this way can be stored for a long time and, at the same time, reliably prevent contamination with harmful gases from the ambient air. It can be filled with a protective gas. The films 32.1 and 32.2 are preferably formed pierceable.

3 schematically shows the construction of a measuring device 10 according to the invention. This comprises a measuring cell 12, a humidity and temperature sensor 34 and a pump device 20, wherein the protruding elements are connected to an evaluation unit 26. The connection between the humidity and temperature sensor 34 takes place in this case via terminals 52, that of the pumping device 20 by means of connections 54. The humidity and temperature sensor 34 is arranged between the measuring cell 12 and the pumping device 20, wherein the pumping device 20 below the measuring cell 12 with respect to the marked by arrows 50 (Schad-) Gas flow is arranged.

The measuring cell 12 has a receptacle 14, in which a tube-shaped detection means 16 is received. In this case, a light source 22 is arranged on one longitudinal side of the detection means 16, and a light receiver 24 is arranged opposite this on the other longitudinal side of the detection means 16. Between these, a light channel 46, represented by an arrow, is arranged. The light source 22 is connected via connections 42, the receiver means 24, which is preferably designed as a photodiode, via terminals 44 to the evaluation unit 26. The light source 22 is also preferably designed as an LED. The pollutant gas 50 flowing through the detection means 16, which is received in the measuring cell 12, reacts by flowing with a preferably constant and high volume flow, generated by the pumping device 20, with the arranged on the inner wall 28 of the tube-shaped support means of the detection tube 16 Coating 18, in which an indicator substance which is sensitive to the harmful gas is immobilized. By means of transmission measurements in the light channel 46, a voltage change is first detected which can be recalculated in the evaluation unit 26 in a transmission change and thus an absorption change as a function of time can be determined. By means of a software implemented in the evaluation unit 26, an unknown pollutant gas concentration can then be determined. Calibration is also possible directly via the voltage change.

4 now shows a longitudinal section through the measuring cell 12 according to FIG. 3 in a plane which leads through the light source 22 and the receiver means 24. The measuring cell 12 is formed in two parts, with a preferably fixed part 13.1 and a movable part 13.2. The movable part 13.2 can be placed in the direction of arrows 38 on the immovable part 13.1. The movable part 13.2 is releasably connected to the stationary part 13.1, so that it is possible to use a detection means 16 formed by a tubular support means 17 with a coating 18 arranged on its inner wall, this also being gas-tight at both ends Foil can be closed. In the area of a noxious gas inlet 64 or a noxious gas outlet 66, the part 13.1 or 13.2 of the measuring cell 12 has a groove 58.1 or 58.2, which is formed circumferentially. In these grooves 58.1 and 58.2 sealing means 56.1 and 56.2 are added, which preferably as O-rings with a flattened cross-section are formed. Between these grooves 58.1 and 58.2 and the noxious gas inlet 64 and the noxious gas outlet 66 is in the fixed part 13.1 of the measuring cell 12, a protruding mandrel 60, and correspondingly in the movable part 30.2 of the measuring cell 12, a mandrel 62 is formed. The mandrels 60 and 62 are preferably formed annularly circumferentially without interruption. If, with the measuring cell 12 open, the detection means 16 is inserted into the fixed part 13.1 in the direction of the arrows 38, a gas-tight foil of the detection means 16 arranged at the fixed part 13.1 is punctured by the ring-shaped mandrel 60, in which case the detection means 16 is due to the arranged in the groove 58.1 sealant 56.1 is prevented from contamination with the Atmo- sphere within the measuring cell. Subsequently, the movable part 13.2 of the measuring cell 12 is placed in the direction of arrows 38, wherein the arranged at the end facing the end of the detection means 16 film is pierced by the annular dome 62 accordingly. In this case, a protective gas can always be passed through the device 10. Preferably, when placing the movable part 13.2, an electrical contact is closed, which starts the measuring process. Puncturing of both closure foils during placement of the part 13.2 in approximately the same time is also possible. In this way, a continuous flow channel 40 is formed, in which by means of the light channel 46 in transmission a guided by the detection means 16 noxious gas concentration can be determined. In this case, the supply lines to the measuring cell 12 can be freed from contaminating noxious gases in advance, the supply lines, which are not shown here in detail, being provided in particular with stop valves, so that from the resulting line pieces simply via a connection, which also has a valve , possible noxious gases can be deducted and replaced by a neutral atmosphere or a protective gas. Subsequently, the gas to be measured can then be passed through the detection means 16 in a constant volume flow, generated by means of the pumping device 20.

Fig. 5 shows the measuring cell 12 shown in Fig. 4 in a cross section, guided by the plane of the light source and the receiver means 24, whereby the principle of determining a noxious gas concentration in transmission and the guidance of the light channel 46 is again illustrated.

FIG. 6 now shows an alternative measuring cell 12 which, in contrast to that shown in FIG. 4, has a total of three light sources 22 and correspondingly three receiver means 24, in particular designed as photodiodes. In this way, on the one hand, the sensitivity of the measuring device 10 can be considerably increased, but it is also possible light, that in Providence of multiple indicator substances that are sensitive to different noxious gases, here matched to this different light sources 22 are used, ie those with different wavelengths. Accordingly, the receiver means 24 are then formed here.

FIG. 7 now shows a third embodiment of a measuring cell 12, in which case the inner wall 36 of the tubular receptacle 14 is formed with a reflecting surface. The light source 22 and the receiver means 24 are arranged on one side of the detection means 16 in the fixed part 13.1 of the measuring cell 12. The arrangement takes place at an angle to each other. In this case, the path of a light beam emitted by the light source 22 is reproduced with an arrow 48 which, in the example given, is reflected seven times on the reflective inner wall 36 of the tubular receptacle 14 before it strikes the receiver means 24. This also makes a considerable increase in the sensitivity of the measuring device 10 possible.

Finally, FIG. 8 shows a fourth embodiment of a measuring cell 12, the light source 22 being arranged here in the stationary part 13.1 on its front side, whereas a total of four receiver means 24 are arranged on the opposite side, relative to the detection means 16. In the region of the stationary part 13.1 of the measuring cell 12 opposite this, in one embodiment, a light guide 68 is arranged, which allows a light channel 16 over the entire cross-sectional area. As a result, the cross section of the output from the light source 22 light channel is considerably expanded. In an alternative to this, the light source 22 is subsequently formed with a light entry shaft 68, which has a reflective layer on a wall 70, so that, as shown by way of example at the two light beams 48, the light reflects there on this wall 70 and onto the receiver means 24 is headed. This also results in a fanning out of the width of the light beam emitted by the light source 22, so that a voltage or transmission change can be detected by means of a plurality of receiver means 24.

The light source 22 can in principle be designed such that it additionally has focusing means, as a result of which a further increase in the sensitivity of the measuring device 10 is achieved. Example 1 :

For cleaning, the glass tubes made of borosilicate glass of the mark Sl MAX ^® , Kavalier, Säzava, Czech Republic, 3 cm in length, with an outer diameter of 6 mm and a wall thickness of 1 mm at room temperature in a solution of 70 vol .-% of conc , Sulfuric acid and 30 vol .-% Wasserstoffproxidlösung (30% in water) for one hour in an ultrasonic bath. The glass tubes were washed three times with distilled water and dried in an oven at 50 ⁰ C overnight.

In the absence of UV light, 600 mg of silicone-polycarbonate membrane (product name SSP-M213, Specialty Silicone Products, Inc., New York, USA) was used in a rolled-edge glass with a solution of 18 mg of N, N'-diphenyl-1 , 4-phenylenediamine (Aldrich, Steinheim, Germany) in 10 ml chloroform pa (Aldrich, Steinheim, Germany) and stirred until the dissolution of the membrane. For the preparation of the detection tubes, the glass tubes were attached at one end by means of a spring arm tweezers to a height adjustable by means of a stepping motor holding device, product name BGS60 the company EAS GmbH, Rheinberg, Germany. With the help of this device, the glass tubes were at a rate of 36 cm ^• min ^"1 immersed in the prepared solution to a depth of 2.8 cm, and after 10 s at a speed of 22.5 cm ^{■ min" 1} again from the solution pulled out. The glass tubes coated internally and externally in this way were dried vertically for 30 minutes in room air. To remove the outer coating, the inside and outside coated glass tubes were rubbed on the outside with an acetone-soaked, lint-free cloth. The detection tubes thus produced with a layer thickness of the coating of about 1 .mu.m were suitable for the determination of nitrogen dioxide in gaseous samples.

The measuring cell used for the measurement consisted of an LED with 435 nm peak wavelength as light source and a photodiode with integrated OPT-301 operational amplifier from Burr-Brown (reference: GMS, Karlsruhe, Germany) as photoreceiver. The analog voltage signal of the photoreceiver was measured by means of a 12-bit A / D

Converter module LTC 1293 (manufacturer: Linear Technology) converted into a digital voltage signal. The a miniature diaphragm pump NMP 015 B company KNF Neuberger, Freiburg, Germany, generated suction caused in the detection tube a flow of the gaseous sample of 1380 ml ^■ min ^"1, which by means of an up au- ßerhalb the measuring cell located mass flowmeter of the type F-11 1 C-HAD-33-P (Bronkhorst Hi-Tec, Ruurlo, The Netherlands). content of the gaseous sample was determined directly after the exit of the gas from the detection tube using a digital humidity and temperature sensor SHT75 from Driesen + Kern GmbH, Bad Bramstedt, Germany.

The reactivity of the prepared detection tube with respect to nitrogen dioxide was in dry gaseous samples having an average temperature of 24.7 ⁰ C ± 1, 5 ⁰ C and a volume fraction of nitrogen dioxide in synthetic air (20.5% O ₂ in N ₂ (Messer Griesheim GmbH , Krefeld, Germany)) between 2 ppm and 25 ppb. The nitrogen dioxide was taken from test gas cylinders (Messer Griesheim GmbH, Krefeld, Germany) and the desired concentration and volume flow by diluting with synthetic air by means of mass flow controllers type F-201C-RAA-33-E Bronkhorst Hi-Tec, Ruurlo, Netherlands, discontinued.

It was found that at the beginning of the measurement, the voltage signal of the photoreceiver changed linearly with time (see FIGS. 9 and 10), ie. H. the rate at which the voltage signal of the photoreceiver changed was approximately constant at a given gas concentration in the initial region. The speed with which the voltage signal of the photoreceiver changed was determined from the range of the voltage change from -15 to -200 mV, when the latter value was not reached up to a measuring duration of 180 s.

A linear relationship was found between the rate at which the voltage signal of the photoreceptor changed and the concentration of nitrogen dioxide (see Figure 11).

The regression parameter is excellent here with R ² = 0.999. By dividing the voltage value of the photoreceiver during the measurement by the voltage value of the photoreceiver before the measurement, the voltage values could be converted into transmission values. This was made possible by the high linearity between voltage signal and light intensity of the photoreceiver. With the aid of the linear calibration function obtained, it was possible with the aid of the described detection tubes for the detection of nitrogen dioxide to determine unknown concentrations of nitrogen dioxide in gaseous samples with high accuracy and reproducibility. The high sensitivity resulted in very short measurement times of about 180 s at 25 ppb and 22 s at 2 ppm nitrogen dioxide. The prepared detection tubes were under exclusion of light and under argon atmosphere for a period of at least one month storage stable. The coating material used for the detection tubes is stable over a period of at least 1 year.

Example 2:

The preparation of the detection tubes was carried out as in Example 1, but the coating solution consisted of 800 mg of silicone-polycarbonate membrane (product name SSP-M213, Specialty Silicone Products, Inc., New York, USA), which was treated with a solution of 4 mg 4,4'-dinonoxy-7,7-dimethoxy-indigo (Dr. G. Voss, University of Bayreuth, Germany) in 10 ml chloroform pa (Aldrich, Steinheim, Germany) and stirred until the dissolution of the membrane. The detection tubes thus produced with a layer thickness of the coating of about 2 μm were suitable for the determination of ozone in gaseous samples.

The measuring cell used for the measurements differed from the measuring cell used in Example 1 in the LED used as the light source. At this point an LED with a peak wavelength of 650 nm (product name ELD-650-523 from Roithner Lasertechnik, Vienna, Austria) was used.

The reactivity of the detection tubes prepared to ozone was ppm in dry gaseous samples having an average temperature of 22.9 ⁰ C ± 1, 5 ⁰ C and a volume fraction of ozone in air between 340 and ppb examined 25th It also found a linear relationship between the rate at which the voltage signal of the photoreceptor changed at the beginning of the measurement and the concentration of ozone. With the aid of the linear calibration function thus obtained, it was possible to determine unknown concentrations of ozone in gaseous samples with the aid of the described detection tubes for the detection of ozone. The coating material used for the detection tubes is stable over a period of at least 6 months.

Claims

claims

1. Measuring device (10) for the optical determination of the concentration of at least one noxious gas in transmission, comprising an opaque measuring cell (12) with a receptacle (14), in which a tube-shaped, at least partially transparent detection means (16) which on its inner wall at least partially a translucent coating (18) with a predetermined layer thickness of at least one polymeric material having at least one immobilized in this indicator substance is arranged, further comprising a the detection means (16) upstream or downstream pumping or suction device (20), which a Schadgasstrom passes through the detection means (16), and at least one light source (22) and at least one receiver means (24), which on one and / or more sides of the detection onsmittels (16) are arranged, by means of which in transmission an absorption change of Indicator substance as a function of the time t is measured, wherein the receiver means (24) with an evaluation unit (26) is connectable.

2. Measuring device according to claim 1, characterized in that the coating (18) has a thickness in a range of 0.1 .mu.m to 1 mm.

3. Measuring device according to one of the preceding claims, characterized in that the detection means (16) at its two ends (30.1, 30.2) with a gas-tight film (32.1, 32.2) is provided.

4. Measuring device according to one of the preceding claims, characterized marked, that the receiver means is designed as a photodiode, phototransistor and / or photoresistor.

5. Measuring device according to one of the preceding claims, characterized in that the pumping or suction device (20) sucks the noxious gas with a constant volumetric flow.

6. Measuring device according to one of the preceding claims, characterized in that it has a humidity and / or temperature sensor and / or a mass flow sensor (34).

7. Measuring device according to one of the preceding claims, characterized in that a wall (36) of the receptacle (14) is at least partially provided with a reflective surface.

8. Detection agent according to one of claims 1 to 3.

9. A method for the optical determination of at least one noxious gas in transmission, wherein at a constant volume flow, a noxious gas flow through a in a measuring cell (12) arranged detection means (16) is guided, which has a coating (18) of at least one polymeric material in which at least one indicator substance is immobilized, wherein at least one light beam is passed through the detection means (16), and wherein at least in a partial region the speed of the measurable transmission or voltage change and / or the rate of absorption change is approximately linear with the gas concentration runs.

10. The method according to claim 9, characterized in that the light beam is at least twice performed by the detection means (16).