EP2673632A1 - Arrangement and method for detecting hydrogen peroxide - Google Patents

Abstract

The invention relates to an arrangement for detecting hydrogen peroxide. The arrangement comprises a sample space (12) for receiving a hydrogen-peroxide-containing gas, wherein the sample space (12) is fluidically connected to a hydrogen-peroxide-selective colorimetric detection reagent (28), at least one radiation source (32) for irradiating the detection reagent (28) and at least one detector (34) for detecting at least one optical property of the colorimetric detection reagent. An arrangement of this type enables detection of hydrogen peroxide in the gaseous phase without the need to transfer hydrogen peroxide to the liquid phase. As a result, a simplified measurement behaviour and additionally a highly sensitive measurement are attained.

Description

 description

title

 Arrangement and method for detecting hydrogen peroxide

The present invention relates to an arrangement and a method for

Detecting hydrogen peroxide, especially in one

hydrogen peroxide-containing gas.

State of the art

Hydrogen peroxide is widely used in many applications.

For example, it is used as an oxidizing agent, bleaching agent or for disinfecting and sterilizing in industrial applications or in the field of medicine. In addition, hydrogen peroxide is used in agriculture or other biological applications, such as

Oxygenation.

For detecting hydrogen peroxide are various sensors

or known method. In particular, optical sensors based on the change of optical properties of a substance due to the influence of hydrogen peroxide are used.

For example, it is known from Otto S. Wolfbeis, Reversible Optical Sensor Membrane for Hydrogen Peroxide Using an Immobilized Fluorescent Probe, and its Application to a Glucose Biosensor, Microchim. Acta 143, 221-227 (2003), to embed europium-tetracycline complexes in a polyacrylonitrile-co-polyacrylamide polymer matrix and fluorescence behavior in one

hydrogen peroxide-containing solution to detect hydrogen peroxide. Another approach known from Aleksandra Lobnik, Sol-gel optical sensor for continuous determination of dissolved hydrogen Peroxide, Sensors and Actuators B 74 (2001), 194-199, consists in

Use of the indicator Meldola Blue. This is incorporated in sol-gel layers and brought into contact with an aqueous hydrogen peroxide-containing solution. The influence of hydrogen peroxide changes the optical properties of the indicator, which can be evaluated spectrophotometrically.

Another known detection for hydrogen peroxide is based on a reaction of hydrogen peroxide with titanium (Ti (IV)) complexes. For example, Yuichi Komazaki, Automated measurement System for H ₂ O ₂ in the atmosphere by diffusion scrubber sampling and HPLC analysis of Ti (IV) -PAR-H ₂ 0 ₂ complex, Analyst, 2001, 126, 587-593 discloses that Hydrogen peroxide in the atmosphere can be washed in a liquid solution and there spectrophotometrically detected using a Ti (IV) -PAR complex.

Disclosure of the invention

The present invention is an arrangement for detecting hydrogen peroxide, comprising a sample chamber for receiving a hydrogen peroxide-containing gas, wherein the sample chamber is fluidically connected to a hydrogen peroxide-selective colorimetric detection reagent, further comprising at least one radiation source for irradiating the

Detection reagent, and at least one detector for detecting

at least one optical property of the colorimetric

 Detection reagent.

In the context of the invention, a hydrogen peroxide-selective colorimetric detection reagent is understood in particular to mean a substance which is suitable for the detection of hydrogen peroxide on the basis of optical properties. He can only detect hydrogen peroxide, so be selective only for this substance, or next

Hydrogen peroxide detect other substances, so be selective for this. However, it is advantageous that the detection reagent is not selective for any further substances contained in the hydrogen peroxide-containing gas, so as not to permit the qualitative and quantitative detection of hydrogen peroxide to disturb. The detection reagent according to the invention also serves a colorimetric detection, ie a detection based on a change of at least one optical property. Under at least one optical property is in particular the absorption behavior or the

Emission behavior of the colorimetric detection reagent understood. This means, for example, that the detection reagent absorbs radiation of a specific wavelength, the wavelength being particularly dependent on the formation of a complex with hydrogen peroxide. The different absorption behavior can then be measured, for example, by the detector via an absorption spectrum. However, other possibilities according to the invention are conceivable, with which the specific and hydrogen peroxide-dependent absorption behavior can be examined, for example, an investigation of the transmission or

Fluorescence behavior.

A detection reagent which is fluidically connected to the sample space in the context of the invention also means, in particular, that the detection reagent is arranged in the sample space itself or in a separate space, which is fluidically connected to the sample space. In this case, the detection reagent can be arranged, for example, centrally in the respective room or on a wall of the room. It is also advantageous if the detection reagent is arranged such that the hydrogen peroxide-containing gas flows along it. According to the present invention, an optical sensor for

 Hydrogen peroxide created, with the hydrogen peroxide directly in the gas phase is measurable. According to the invention, it is therefore not necessary to convert the hydrogen peroxide to be detected, for example by condensation processes, gas scrubbing processes or other processes, from the gas phase into a liquid phase and the liquid phase, for example an aqueous phase

Solution to measure. Rather, the gas phase can be used directly as a measuring medium and transferred into the arrangement or in the sample space. As a result, a detection of hydrogen peroxide with the arrangement according to the invention can be carried out very inexpensively. The arrangement according to the invention is also very cost-effective

can be produced, since it is composed essentially only of a radiation source, a sample chamber with detection reagent and a detector. As a result, both the manufacture and the operation and maintenance of the

inventive arrangement not associated with disproportionately high costs.

Furthermore, the arrangement according to the invention is very compact formable, which makes it particularly easy to design the arrangement, for example, as a portable sensor. As a result, for example, the ambient air can be examined locally, which allows a great flexibility of the possible fields of application with the arrangement according to the invention. Therefore, in-situ measurements are possible, for example, directly reaction gas or the like can be passed into the sample space, so that, for example, a

Process-related control of a variety of possible processes is possible.

With the arrangement according to the invention, it is also possible to be able to qualitatively and quantitatively detect by an increased sensitivity even the smallest amounts of hydrogen peroxide. In particular, it is with the

Arrangement of the invention possible to detect and quantify traces of hydrogen peroxide in a range of> 0, 1 ppb, for example, up to a range of <1000ppb. In the context of an advantageous embodiment of the present invention, the at least one radiation source is designed as a UV / Vis radiation source. This means in particular that the radiation source is designed to emit radiation having a wavelength in a range of> 200 nm to <800 nm. The exact wavelength or the exact

Wavelength range in particular depending on the optical properties of the colorimetric detection reagent or its

Absorption behavior selected. Radiation sources in the UV / Vis range are widespread and thereby easily and without disproportionately costly effort available. Measurements by means of IR spectroscopy, which are often considerably more expensive to carry out, can therefore be dispensed with in this embodiment, which is the one use of the arrangement according to the invention very simple. In addition, a UV / Vis radiation can be used in a particularly suitable manner to the optical

Properties, such as the absorption behavior, a wide number of

To investigate detection reagents.

Within the scope of a further advantageous embodiment of the present invention

Invention, the at least one radiation source is designed as a light-emitting diode. By light emitting radiation of a well-defined wavelength can be generated, which thus allows a very accurate measurement of hydrogen peroxide. In addition, light-emitting diodes are inexpensive to manufacture and in operation, which also makes the operation of the arrangement according to the invention more cost-effective. In addition, light emitting diodes can be operated with a low power consumption, which also makes the power consumption of the entire arrangement low. As a result, this embodiment of the arrangement according to the invention is particularly suitable for portable applications, since inappropriate high energy reserves, such as a variety of mostly heavy and thus unwieldy batteries, can be dispensed with.

Within the scope of a further advantageous embodiment of the present invention

Invention, the at least one detector is designed as a photodiode. By means of a photodiode can easily detect the detected radiation in

electrical current or converted into electrical voltage and evaluated in this way. Photodiodes offer one

excellent accuracy to even the lowest concentrations of

Hydrogen peroxide can be detected and quantified in the hydrogen peroxide-containing gas.

Within the scope of a further advantageous embodiment of the present invention

Invention, the detection reagent comprises an organometallic or

inorganic complex compound such as a titanium (IV) complex. such

Complexes are particularly well suited as colorimetric detection reagents since even the lowest concentrations of hydrogen peroxide can be reliably detected with them. In principle, from such complexes by the action of hydrogen peroxide, colored peroxide complexes can be formed, which in turn are readily detectable. Within the scope of a further advantageous embodiment of the present invention

Invention, the detection reagent is arranged in a porous organic or inorganic matrix. This allows a well-defined

Contact surface of the reagent can be achieved with the hydrogen peroxide-containing gas, which makes precisely defined and reproducible measurement conditions possible. Furthermore, a porous matrix is well suited to be traversed by a gas, or a gas in the matrix

to diffuse, which in turn allows very suitable measurement conditions and also simplifies the arrangement of the reagent, for example in the sample space. In this way, a great flexibility is made possible with regard to the configuration of the arrangement according to the invention. In addition, in this way, the detection reagent, when consumed and needs to be renewed, can be easily exchanged by, for example, renewing the matrix.

Preferably, the matrix is formed of one or more oxides of a metal, such as aluminum, or a semi-metal, such as silicon or boron. Further, a silicate matrix or metallosilicate matrix selected, in particular, from the group of zeolite-containing materials may be used. Further, an organic polymer matrix such as a matrix of ethyl cellulose or a polystyrene resin may also be used in the present invention. This makes it possible for the fluid to be measured to come into optimal contact with the detection reagent. Those matrix-forming materials interact only insignificantly with the hydrogen peroxide. The

Detection of hydrogen peroxide is thus not disturbed by such materials. It is further preferred that the matrix is porous. It is particularly preferred that the matrix is a mesoporous matrix. A mesoporous matrix is characterized by its pore diameter, which ranges from> 2nm to <50nm. With such pores, a particularly advantageous contact between the hydrogen peroxide-containing gas and the

Detection reagent can be realized. Alternatively, the matrix may be microporous, in which case the pore diameter is in a range of <2 nm. This means, in particular, that the pores present on average are mesoporous or microporous, since there may always be deviations from the microporous or mesoporosity. Within the scope of a further advantageous embodiment of the present invention

Invention, a light guide is provided, which is arranged such that radiation emitted by the radiation source is guided in the light guide, and which comprises the colorimetric detection reagent such that it can be irradiated by the emitted radiation. For example, an optical waveguide may be used, which may be made of glass or a plastic.

For example, the light guide can be used with the colorimetric

Be coated detection reagent. The light guided in this way or the radiation guided in this way then interacts with the detection reagent, the optical properties being detectable by the detector.

Within the scope of a further advantageous embodiment of the present invention

Invention, the sample chamber on a gas inlet and a gas outlet, wherein valves are provided in the gas inlet and in the gas outlet. As a result, a precisely defined gas volume can be introduced into the sample space, which can then be measured over a longer period of time. In this embodiment, it can be ensured in a particularly simple manner, even with a potentially long response time of a detection reagent, that accurate measurement results can be achieved even at very low concentrations.

The present invention further provides a method for detecting hydrogen peroxide, comprising the steps of: introducing a

hydrogen peroxide-containing gas in a sample space to the

hydrogen peroxide-containing gas with a hydrogen peroxide-selective colorimetric detection reagent in contact; Irradiating the detection reagent with radiation of defined wavelength; Detecting at least one optical property of the colorimetric reagent.

With the method according to the invention, with reference to the

According to the invention described advantages are achieved.

In particular, it is possible with the method according to the invention

To detect hydrogen peroxide directly in the gas phase qualitatively and quantitatively. It thus becomes possible to carry out an analysis method which is simple to carry out, without causing disproportionate costs and thereby the hydrogen peroxide to be detected can be detected with an accuracy of up to 0.1 ppb.

In the context of an advantageous embodiment of the invention

Method, the detection reagent is irradiated with a wavelength in a range of> 200nm to <800nm. Consequently, radiation in the UV / Vis range is used. The exact wavelength used here depends in particular on the type of colorimetric detection reagent used. Such radiation is particularly suitable to investigate the optical properties, or the absorption or emission behavior of a variety of hydrogen peroxide-selective detection reagents and is thereby produced easily and inexpensively.

Further advantages and advantageous embodiments of the objects according to the invention are illustrated by the drawing and explained in the following description. It should be noted that the

Drawing has only descriptive character and is not intended to limit the invention in any way. 1 shows a schematic cross section of an arrangement according to the invention.

FIG. 1 schematically shows an arrangement 10 according to the invention

Detecting hydrogen peroxide shown. By such

Arrangement 10 according to the invention makes it possible to qualitatively and quantitatively determine hydrogen peroxide directly in the gas phase of a gas containing hydrogen peroxide. The assembly 10 may be formed, for example, as a fixed sensor and serve as a laboratory equipment. In addition, the assembly 10 can be used as a portable sensor, in particular for analysis of the atmosphere, room air, or for in situ applications.

The arrangement 10 according to FIG. 1 comprises a sample space 12 for receiving a hydrogen peroxide-containing gas whose hydrogen peroxide content is to be qualitatively and / or quantitatively investigated. For this purpose, the

Sample chamber 12 preferably a gas inlet 14 and a gas outlet 16. In this way, the sample space 12 with the hydrogen peroxide-containing

Gas can be flowed through. For example, to achieve that to be examined hydrogen peroxide-containing gas for a longer measurement cycle within the sample chamber 12 remains, can in the gas inlet 14 and in the

Gas outlet 16 valves 18, 20 may be provided to close the gas inlet 14 and the gas outlet 16 gas-tight.

Furthermore, a flow meter 22, 24 may be provided in the gas inlet 14 and / or in the gas outlet 16 to determine which volume of gas flows into or out of the sample space 12. By incorporating the thus determined precise volume, a quantitative measurement can be made very accurate. Alternatively or additionally, a pressure measuring device 26 may be arranged in the sample space 12 in order to determine the pressure of the hydrogen peroxide-containing gas present in the sample space 12 and thus also to close the amount of gas located in the sample space 12.

The sample chamber 12 is fluidically connected to a

hydrogen peroxide-selective colorimetric detection reagent 28. This means that the detection reagent 28 is arranged in the sample space 12 itself, or in a space fluidically connected to the sample space 12. According to FIG. 1, the detection reagent 28 is arranged in the sample space 12 itself. The detection reagent 28 may be immobilized in the sample space 12 in any suitable manner, such that the

hydrogen peroxide-containing gas can come into contact with the detection reagent 28, whereby the hydrogen peroxide with the detection reagent 28th

interacts or responds.

According to FIG. 1, the detection reagent 28 is arranged in a matrix 30. The matrix 30 is preferably mesoporous, and the detection reagent 28 may be located in the corresponding pores. In the case of a mesoporous matrix 30, these pores have a diameter in a range of> 2nm to <50nm. This can be an appropriate amount of

hydrogen peroxide-containing gas flow or diffuse into the matrix 30 and thus react with the detection reagent 28. Particularly preferably, the detection reagent 28 is arranged in a porous organic or inorganic matrix 30. As advantageous examples may be mentioned a mesoporous matrix formed of one or more oxides of one Metal, such as aluminum, or a semi-metal such as silicon or boron. Further, a microporous silicate matrix may be used

Metallosilicatmatrix be used, which is particularly selected from the group of zeolite-like materials. Furthermore, an organic polymer matrix, such as a matrix of ethyl cellulose or a

 Polystyrene resin find use according to the invention.

Advantageously, the detection reagent 28 is embedded in the matrix 30 in such a way that its optical and chemical properties in the

Maintained essentially and also a substantially undisturbed

Diffusion of the hydrogen peroxide-containing gas in the matrix 30 is possible.

The hydrogen peroxide-selective colorimetric detection reagent 28 serves to detect hydrogen peroxide qualitatively and quantitatively.

Particularly suitable according to the invention are organometallic or inorganic complex compounds which are obtained by the action of

Hydrogen peroxide, for example, can form colored peroxide complexes. Particular preference is given to complexes of the fourth, fifth and sixth main group of the Periodic Table of the Elements, it being possible with particular preference to use titanium (IV) complexes. Exemplary titanium (IV) -

Complexes which can be used in a particularly suitable manner according to the invention are, for example, titanium (IV) porphyrin complexes,

or derivatives thereof. At least one by an interaction or reaction of the

Detecting reagent 28 with the hydrogen peroxide changed optical property, such as the absorption properties or

Emission properties of the detection reagent 28 to be able to examine the inventive arrangement 10 further comprises at least one

Radiation source 32 for irradiating the detection reagent 28. The at least one radiation source 32 is preferably formed as a UV / Vis radiation source. This means that the radiation source 32 light with a

Wavelength in a range of> 200nm to <800nm and at least a portion of the sample chamber 12 and the

Detection reagent 24 irradiated at this wavelength. It is particularly preferred that the radiation source 32 is formed as a light emitting diode. Furthermore, the arrangement 10 comprises at least one detector 34 for

Detecting at least one optical property of the colorimetric detection reagent. By the detector 34, for example, the

Absorption behavior or the emission behavior of the

Detection reagents 28 are examined before and in particular after the reaction with the hydrogen peroxide and thereby the change of this behavior are determined qualitatively and quantitatively, resulting in a qualitative and quantitative analysis of the hydrogen peroxide content in the

hydrogen peroxide-containing gas allows.

The detector 34 is therefore expediently an optical detector. Particularly preferably, the detector 34 is designed as a photodiode. But other types of detectors are possible according to the invention. Examples include a photoresistor and a phototransistor.

In this case, the radiation source 32 may be able to be switched off or shut off by an electrical control, the control preferably also being connected to the detector 34 and / or the valves 18, 20.

A method according to the invention for detecting hydrogen peroxide carried out with the arrangement according to the invention proceeds as follows. First, a hydrogen peroxide-containing gas, whose

Hydrogen peroxide content is measured, introduced into the sample chamber 12 of the assembly 10. For this purpose, for example, it passes through the gas inlet 14. In this case, both a continuous introduction of the gas into the sample chamber 12 is possible, as well as an intermittent introduction, wherein the gas for a defined period of time may remain in the sample chamber 12 for the measurement. In the sample chamber 12, or in a fluidically connected to the sample chamber 12 space, the hydrogen peroxide-containing gas is characterized with the

hydrogen peroxide-selective colorimetric detection reagent 28 brought into contact. For example, the gas enters the pores of the matrix 30 in order to react there with the colorimetric detection reagent 28.

The hydrogen peroxide causes a change in the optical properties of the detection reagent 28, such as the spectral Absorption properties or emission properties, which can be detected by means of the radiation source 32 and the detector 34 and thus allow determination of the hydrogen peroxide in the gas phase.

For this purpose, the sample space 12, ie the detection reagent 28, is consequently irradiated with defined radiation by the radiation source 32. For this purpose, radiation of a wavelength in a range of> 200 nm to <800 nm, depending on the detection reagent, is preferably used.

After the measurement, the gas is slid out of the sample space 12, and passes, for example, the gas outlet 16. The detection reagent 28 can usually be used for a plurality of measurement cycles or for a specific measurement period before it should possibly be regenerated.

In this respect, two main cases can be distinguished. If both the formation and the decomposition of the compound formed by the application of hydrogen peroxide from the detection reagent 28, such as a peroxide complex, are little kinetically inhibited, the thermodynamic equilibrium sets in within a short time. In this case, no regeneration step is required after exposure to the hydrogen peroxide-containing gas. In the absence of hydrogen peroxide, the decomposition of the formed compound of hydrogen peroxide and the detection reagent 28 occurs, so that the detection reagent 28 is essentially recovered. If, however, the decomposition of the compound formed is very slow compared to the formation of the same, so after the application of the

hydrogen peroxide-containing gas and the measurement or a certain number of measurements to perform a regeneration step to the

Re-provision of the arrangement 10 to allow. This can

For example, the temperature can be temporarily increased with the aim of achieving a decomposition of the compound formed or remaining hydrogen peroxide. Moreover, if the detection reagent 28 is not sufficiently stable over a relatively long period of time, in both of the above cases an exchange of the detection reagent 28 can take place, for example by a part of the

 Sensor system is replaced or a reload with detection reagent 28 takes place.

Claims

 Arrangement for detecting hydrogen peroxide, comprising a sample chamber (12) for receiving a hydrogen peroxide-containing gas, wherein the sample chamber (12) is fluidly connected to a

 hydrogen peroxide-selective colorimetric detection reagent (28), further comprising at least one radiation source (32) for irradiating the detection reagent (28) and at least one detector (34) for

 Detecting at least one optical property of the colorimetric detection reagent.

Arrangement according to claim 1, characterized in that the at least one radiation source (32) is designed as a UV / Vis radiation source.

Arrangement according to claim 1 or 2, characterized in that the at least one radiation source (32) is designed as a light-emitting diode.

Arrangement according to one of claims 1 to 3, characterized in that the at least one detector (34) is designed as a photodiode.

Arrangement according to one of claims 1 to 4, characterized in that the detection reagent (28) comprises an organometallic or inorganic complex compound, such as a titanium (IV) complex.

Arrangement according to one of claims 1 to 5, characterized in that the detection reagent (28) is arranged in a porous organic or inorganic matrix (30).

7. Arrangement according to one of claims 1 to 6, characterized in that a light guide is provided, which is arranged such that from the radiation source (32) emitted radiation is guided in the light guide, and which comprises the colorimetric detection reagent (28) such that it can be irradiated by the emitted radiation.

8. Arrangement according to one of claims 1 to 7, characterized in that the sample chamber (12) has a gas inlet (14) and a gas outlet (16), wherein in the gas inlet (14) and in the gas outlet (16) valves (18 ), (20) are provided.

9. A method for detecting hydrogen peroxide comprising the steps

Introducing a hydrogen peroxide-containing gas in a sample chamber (12) to the hydrogen peroxide-containing gas with a

 to contact hydrogen peroxide-selective colorimetric detection reagent (28);

 Irradiating the detection reagent (28) with radiation of a defined wavelength;

 Detecting at least one optical property of the colorimetric detection reagent.

10. The method according to claim 9, characterized in that the

 Detection reagent (28) is irradiated with a wavelength in a range of> 200nm to <800nm.