NL8402532A - METHOD AND APPARATUS FOR DETERMINING LOW CONCENTRATIONS OF A GAS DIVIDED SUBSTANCE - Google Patents

Description

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Method and device for determining small concentrations of a substance distributed in a gas.

In vegetable products, especially fruit, ethylene (C 2 H 4) is generated during storage, while the presence of ethylene in the vicinity of such products, especially between densely packed fruit in crates and / or in closed transport or storage areas, can lead to accelerated ripening and rotting. On the other hand, a metered addition of ethylene can lead to a desired effect, for example the blooming of flowers.

However, there are no methods and devices capable of inexpensively determining outside of a laboratory low concentrations of ethylene in air, as required for monitoring stored plant products or dosing ethylene to accelerate the ripening of such products. This also generally applies to all substances distributed in a gas with a low concentration.

The invention provides a method for determining small concentrations of a substance distributed in a gas, which can undergo a chemical reaction with another gas, whereby radiation is emitted, the method being characterized in that the gas sample to be examined with the reaction gas is mixed, the latter being in excess of the substance to be detected, which mixture is then introduced into a closed reaction chamber, which chamber is arranged to convert the radiation generated in this reaction into a radiation for this purpose. radiation sensitive converter, in particular a photomultiplier tube.

The excess of the reaction gas must then be so great that it is ensured that the reaction with the substance to be detected proceeds completely. The number of radiation quanta is then proportional to the number of moles of the respective reaction components, so that by measuring the strength of the radiation the amount of the substance reacting with the reaction gas can also be determined, in particular after calibration 8402532 t 2 ** -2- using reactions with known amounts.

For the detection of, for example, ethylene in air, ozone is used. The reaction between ethylene and ozone is quite complicated, resulting in a number of unstable intermediates. For this, reference can be made to S.S; Que Hee, Am. Ind. Hyg. Assoc. J. J42, 7 (1981). The actual course of this reaction is not important here, but it is important that radiation is generated in one of the partial reactions.

In particular, the sample is heated to increase the reaction rate, which will favorably affect the sensitivity.

If a continuous measurement is desired7, the sample gas flow to the reaction chamber should be kept at a fixed value.

At a relatively weak radiation intensity, the dark current of the radiation converter used may form an important part of the output current, so that it must be removed. To this end, the radiation, for example with the aid of a rotating butterfly or the like, is periodically interrupted, and the output signal is mixed with a comparison signal of the same frequency as the radiation interruption, whereby a signal is obtained, from which the dark current portion has been removed.

The invention further relates to an apparatus for carrying out this method, which is characterized by a mixer for mixing a reaction gas with the gas sample to be investigated, by a reaction chamber immediately following this mixer, and by a radiation converter, the entry window of which is arranged to receive the radiation exiting from the reaction chamber.

When ozone is used as the reaction gas, the mixer is connected to the output of an ozonator.

In particular, the reaction chamber has a mirrored wall, which has a transparent window at the location of the entrance window of the radiation converter, which wall is more particularly substantially spherical. In this manner, all radiation generated in the reaction chamber can be directed to this window 8402532 ar -3-.

Between the exit window of the reaction chamber and the entrance window of the radiation converter, a rotating butterfly is preferably arranged, which can be driven by means of a motor 5, and which is contained in a light-tight envelope with the converter and the reaction chamber, while means are present to produce a measure of the radiation interruption effect of this butterfly corresponding comparison signal. In particular, an auxiliary radiation source IQ and a converter co-operating therewith are used, which co-operate with a second butterfly, which is mounted on the same axis as the first, but is disposed outside the light-tight envelope, which converter thus has an interruption effect of the first butterfly corresponding comparison signal le-15 vert.

In order to increase the reaction rate, means may be provided with which the gas sample to be tested is preheated.

In the continuous taking of gas samples, a flow stabilizer, in particular a capillary tube, with which a fixed feed rate can be maintained, while the reaction chamber of a connection for suction of the sample under test, is incorporated in the supply pipe for the gas sample. is provided. In particular, the reaction chamber can be formed by a flat bottom glass flask, which bottom is used as the radiation exit window, while the gas supply is introduced through the neck of this flask.

The invention will be elucidated below 2 ° on the basis of a drawing; 1 shows a schematic cross section through an apparatus for carrying out the method according to the invention; Fig. 2 shows a schematic section through a preferred ozonator for this device.

Fig. 1 schematically shows a preferred embodiment of the device according to the invention. This includes as main part a reaction chamber 1 - * 8402532

Cf * -¼ -4- with a substantially spherical wall 2 and a flattened end face 3. For this purpose, use can in particular be made of a glass flask with a flat bottom. The wall 2 outside the flat part 3 is provided with an external mirror layer 45.

Opposite the flattening 3, a tube 5 protrudes through the wall; when using a glass flask, the tube 5 can be inserted through the neck thereof. This tube 5 then ends approximately in the middle of the chamber 101. laterally thereof, a suction tube 6 opens into the chamber 1, which must be connected to a suction pump (not shown). .

The tube 5 also has a narrowing 7, behind which an inner tube 8 ends, which is surrounded by an outer tube 9. The tube 8 is the supply tube for a gas sample to be examined, while the tube 9 is connected to an ozone source. When continuous sampling is to take place, a capillary 10 can be accommodated in tube 8, which ensures a substantially fixed current. Of course, other means for stabilizing the current can also be used. An acceleration occurs in the constriction 7, the gas sample drawn in being mixed well with the ozone drawn in through the pipe 9. The entire assembly is designed in such a way that a large ozone excess is present in the gas sample relative to the amount of the substance to be detected.

The gas mixture reacts in chamber 1, the reaction with ozone giving rise to radiation. There is a fixed relationship between the number of radiation quanta and the number of moles of the reaction constituents.

The reflective layer 4 ensures that the radiation can only exit through the flat wall portion 3.

Behind the flat wall 3, a sensitive radiation detector 11 is arranged, in particular a photo-multiplication tube, which can supply a current proportional to the received radiation quanta, so that this current is a measure of the quantities of the reaction constituents participating in the reaction. . Since there is a large excess of ozone, a complete conversion of the constituent of the gas morphster to be detected is ensured, the strength of the radiation phenomenon being determined by the amount of this constituent in the sample.

Of course, at least the butterfly 12, the window 3 and the transducer 11 must be contained in a light-tight enclosure, which is indicated schematically at 14. The reaction rate in the case of ethylene as the component to be detected is relatively slow, so that the reaction takes place mainly in space 1. To ensure that the reaction proceeds as completely as possible, a relatively large reaction chamber 1 is used, for example with a volume of 11, whereby the suction connection 6 is arranged in such a way that a sufficient residence time in chamber 1 is obtained.

15 It may also be recommended to increase the reaction rate by preheating the gas sample, for example using an electric heating part around or in the pipe 8. e

The radiation converter 11 provides, even when no radiation is incident, a so-called dark current, the (average) strength of which depends, inter alia, on the temperature, and which makes the measurement of weak radiation (i.e. small concentrations of the component to be determined) more difficult.

In order to switch off the effect of the dark current, the radiation can be periodically interrupted with the aid of a butterfly 12, which is driven by a motor 13, while the pulse signal thus obtained is sent to an amplifier 15 with a narrow pass band around the interrupt frequency. sent. In particular, an amplifier can be used for this purpose, which multiplies the pulse signal by a comparison signal with the interruption frequency. The latter can be obtained, for example, by means of an auxiliary radiation source 16 and an associated transducer 17, which are located on either side of an auxiliary butterfly 18, which is also placed on the shaft of the motor 13, but is located outside the enclosure 14. The converter 17 is connected to a control input of the amplifier 15. The output of amplifier 15 is connected to a pointing or writing device 19.

8402532

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Advantageously, a corona ozonator is used to supply a sufficient amount of ozone, which is shown schematically in Fig. 2. It comprises two coaxial tubes 20 and 21, which are located on the sides of metal layers 22 and 5 facing away from each other. 23 are provided, while air can be drawn through the intermediate space 24. The layers 22 and 21 are connected to a high voltage source (Tesla transformer) in order to obtain a continuous corona discharge in space 24. The length of the tubes 20 and 21 determines the ozonation effect.

Such a device can be designed as a portable device. For example, a gas flow rate of 3.1 l / min can be continuously drawn through chamber 1 (i.e. the content is refreshed 3 times / min), of which 15 2/5 l / min air sample and 0.5 l / min ozone. This device is primarily designed for the detection of ethylene in air, but can be used for all substances that emit radiation when reacting with ozone.

If another reaction is to be used, the ozonator must, of course, be replaced by a source of the relevant reaction gas.

8402532 *

Claims (13)

1. Method for determining low concentrations of a substance distributed in one gas, which can undergo a chemical reaction with another gas, whereby radiation is emitted, characterized in that the gas sample to be examined is mixed with the reaction gas the latter being in excess of the substance to be detected, which mixture is then introduced into a sealed reaction chamber which is arranged to convert the radiation generated in this reaction to a converter sensitive to this radiation. specifically a photo multiplier tube. Method according to claim 1 for detecting ethylene, characterized in that ozone is used as the reaction gas. 3. Method according to claim 1 or 2, characterized in that it. gas sample to be examined is pre-heated. 4. Process according to any one of claims 1..3, characterized in that the sample gas flow to the reaction chamber is kept at a fixed value. 5. A method according to any one of claims 1..4, characterized in that the radiation exiting the reaction chamber is interrupted periodically, for example with the aid of a rotating butterfly or the like, and that the output signal is converted into a suitable amplifier. mixed with a comparison signal having the same frequency as the radiation interruption, to obtain a signal from which the dark current portion of the radiation converter has been removed. Apparatus for carrying out the method according to any one of claims 1 to 5, characterized by a mixer (7) for mixing together a reaction gas and the sample of gas to be tested, by means of a directly on this mixer (7 next reaction chamber (1), and by a radiation converter (13), the entry window of which is arranged to receive the radiation exiting from the reaction chamber (1). 8402532 t t -8- Apparatus according to claim 6, characterized in that the reaction chamber (1) has a mirrored wall (4), which has a transmissive window (3) at the entry window of the radiation converter (11). Device according to claim 7, characterized in that the wall (4) is substantially spherical. Device according to any one of claims 6..8, for carrying out the method according to claim 5, characterized in that between the exit window (3) of the reaction chamber (1) and the radiation entry window converter (11) is arranged a rotatable butterfly (12), which can be driven by a motor (13), and which is incorporated in a light-tight enclosure (14) with the converter (11) and the reaction chamber (1) while means are provided to produce a comparison signal corresponding to the radiation interrupt effect of this butterfly (12). Device according to claim 9, characterized in that the means for generating a comparison signal comprise an auxiliary radiation source (16) and a radiation converter (17) co-operating therewith, which co-act with a second butterfly (18), which is mounted on the same axis as the first butterfly (12), but is disposed outside the light-tight enclosure (14). Device according to any one of claims 6..10, characterized in that means are provided for heating the gas sample to be examined. Device according to any one of claims 1..11, intended for the continuous taking of gas samples, characterized in that in the supply pipe (8) for the gas sample is a flow stabilizer, in particular a capillary tube (10). and that the reaction chamber (1) is provided with a connection (6) for extracting the sample under investigation. Apparatus according to any one of claims 1..12, characterized in that the reaction chamber (1) is formed by a flat bottom glass flask (3), the bottom of which is> 8402532 -9- »« r- - -¾ radiation emission window, while the gas supply is introduced through the neck of this flask. % t i * «8402532