WO2000047993A1

WO2000047993A1 - Method and device for determining the toc content of aqueous samples

Info

Publication number: WO2000047993A1
Application number: PCT/EP2000/001066
Authority: WO
Inventors: Jörg BETTMER; Rainer Feldhaus
Original assignee: Institut für Chemo- und Biosensorik Münster E.V.
Priority date: 1999-02-10
Filing date: 2000-02-09
Publication date: 2000-08-17
Also published as: DE19906151A1

Abstract

The invention relates to a method and to a device for determining the TOC content of aqueous samples. According to the inventive method, inorganic carbon compounds in the samples are removed by acidification and the organic compounds are irradiated with UV light and oxidized to carbon dioxide. The carbon dioxide containing sample is run through a electrodialysis unit in which HCO3<-> ions and H<+> ions are produced which pass through corresponding exchanger membranes and enter a pure-water-rinsed measuring chamber. The conductivity of the pure water before entering the measuring chamber and after leaving the measuring chamber is measured and the TOC content is determined on the basis of the respective conductivity values.

Description

Method and device for determining the TOC content in aqueous samples

The invention relates to a method and a device for determining the total organically bound carbon in aqueous samples according to the preamble of the main claim and the subordinate device claim.

In the currently known analysis systems for

Acquisition of the TOC content in aqueous samples in the lower trace range has become the main method in recent years. Both processes have in common the oxidative destruction of the organic water constituents by irradiation with UV light. In this process, all organic compounds are oxidized down to carbon dioxide. Inorganic carbon compounds are removed by acidification in most processes before photo-oxidation. Used here for a simple acid addition and a so-called solid-phase acidifier (US 5,672,516). The differentiation of the above-mentioned methods mainly occurs in the detection.

In one method, the generated CO is removed from the solution by acidifying and passing a gas-permeable membrane (gas-liquid separator). The C0 ₂ is passed into a gas cuvette and measured spectroscopically using infrared radiation.

There is an enrichment in the gas cuvette, the duration of which depends on the expected TOC concentration. The main disadvantages of this method are the impossibility of an on-line measurement or continuous measurement (the typical measurement time here is approximately 10 to 30 minutes) and the fact that auxiliary gases and chemicals are required for the measurement, which increases the operating costs and regular maintenance is required.

In the second method, the measurement solution is passed into a reaction cell. The conductivity is measured and the solution is irradiated with UV light until all organic compounds have been destroyed. The conductivity is measured continuously, which enables reaction control. The TOC content of the solution can be inferred from the conductivity difference determined at the beginning and towards the end of the reaction. Disadvantages here are the impossibility of on-line measurements and the fact that the volume of the reaction solution cannot be varied, which therefore limits the working range of this device to samples with a very low TOC content. The disadvantages of the known methods are thus in summary that the use of chemicals can usually not be dispensed with, which results in a relatively high level of maintenance. In addition, none of the known, commercially available devices enables true on-line monitoring of the TOC content. All known devices for TOC trace analysis also have an extremely limited working range, which severely limits their usability for water samples with higher loads.

The invention is therefore based on the object of providing a method and a device for determining the TOC content in aqueous samples, in which the use of chemicals can largely be dispensed with and which involves both on-line measurement and measurements allow after the stopped-flow method, whereby water samples with a higher TOC content should be measurable.

This object is achieved by the features of the main claim and the subclaim.

The method according to the invention and the device according to the invention have advantages in particular in that the addition of chemicals and gases can be dispensed with entirely. The resulting C0 ₂ does not have to be separated off and the setting of the C0 ₂ / HC0 ₃ ^" balance in favor of the HC0 ₃ ^~ ion is favored by the electrolytic formation of OH ^" ions. The work area can be varied by working in the flow method, which enables true online monitoring or working in the stopped-flow method. The analyte is enriched in the stopped-flow method, so that extremely low detection limits are given. On the other hand, water samples with a higher TOC content can be measured in online operation.

The measures specified in the subclaims make further advantageous developments and improvements possible.

By regenerating the ultrapure water used in the process with the help of an ion exchanger, the outlay on used chemicals can be reduced to a minimum.

The modular structure of the device according to the invention also enables a particularly broad spectrum of analytical problems to be dealt with.

An embodiment of the invention is shown in the drawing and is explained in more detail in the following description.

Show it

FIG. 1 shows a schematic representation of the device according to the invention with its components,

Figure 2 is a schematic representation of the electrodialysis unit.

1 shows the overall system for the analysis of aqueous samples or for the determination of the total organically bound carbon, called TOC, in aqueous samples. The overall system has an ion exchanger unit 1, for example a mixed bed ion exchanger for removing the inorganic carbon and possibly other inorganic substances, a downstream UV reactor 2, an electrodialysis unit 3, a control and evaluation unit 4 and an ion exchanger 5. An option for measuring the conductivity from and after the ion exchanger unit 1 enables the salinity of the sample to be determined.

The electrodialysis unit 3 shown in FIG. 2 has a cathode space 6 with a cathode 7, in which an anion exchange resin is accommodated. Furthermore, an anode space 8 with anode 9 is provided and a measurement space 10 is arranged between anode space 8 and cathode space 6, an anion exchange membrane 11 being provided at the boundary between measurement space 10 and cathode space 6 and a cation exchange membrane 12 being provided between anode space 8 and measurement space 10. The aqueous solution to be measured is fed to the cathode chamber 6 from the UV reactor 2 in accordance with the arrow 13, and the escaping liquid is conducted in accordance with the arrow representation 14 into the anode chamber 8, which it leaves in accordance with the arrow 15. Ultrapure water as the measuring medium, which, for example, emerges from the ion exchanger 5, is, as indicated by the arrows 16, passed through the measuring chamber in countercurrent to the flow in the cathode chamber 6. In each case one conductivity measuring cell 17 is indicated in front of and behind the measuring space 10 by the circuits. In another embodiment, the aqueous solution to be measured can first be passed through the anode compartment and then through the cathode compartment.

The aqueous sample, the TOC content of which is to be determined, is introduced into the unit 1, which is designed in a known manner and in which inorganic carbon compounds are removed or converted. The treated aqueous solution is the UV reactor 2 supplied, in which the aqueous solution is irradiated with UV radiation, all organic compounds being oxidized to carbon dioxide. The UV oxidation should take place catalytically. The sample reaches the cathode space 6 of the electrodialysis unit 3 according to the arrow 13, a variable voltage being applied between the anode 9 and the cathode 7. Hybrid formed are OH ^* at the cathode 7 droxylionen that Genat balance pushes the carbonic acid hydro on the side of HC0 ₃ ^~ ions. The hydrogen carbonate ions formed are actively transported to the anion exchange membrane 11, since the membrane is positively polarized by the applied voltage. This membrane is permeable to the HC0 ₃ ^" ions, so that they reach the measuring chamber in which there is ultrapure water in which an enrichment takes place. The connection 14 leads the sample further into the anode chamber 8, the H ⁺ -Ions through the cation exchange membrane 12, which due to the applied

Voltage is polarized negatively, also get into the ultrapure water present in the measuring room 10.

Before the measuring space 10 is reached, the conductivity of the ultrapure water is measured with the measuring device 17 as the basic value, wherein the temperature can be measured at the same time. After leaving the measuring room 10, a second measurement of the ultrapure water enriched with HC0 ₃ ^{~ is} carried out, and the temperature can also be recorded. Alternatively, the specific resistance of the solution can be used to determine the TOC, but this is also included in the conductivity measurement.

The measured values are fed to the control and evaluation unit 4, using the differences the temperature-corrected conductivity measurement of the measuring medium pure water in front of and behind the measuring room the original TOC content of the sample solution is determined. The measured values are compared with previously determined values. In this context, the conductivity measurement is a relative method in which the method or the device is calibrated beforehand with known standard solutions.

The ultrapure water can be passed continuously through the measuring space 10 to implement on-line monitoring, the difference in the conductivity of the ultrapure water before and after the measuring space being measured continuously. If the quality of the ultrapure water supplied is constant, the continuous measurement of the base value, i.e. the conductivity of the ultrapure water supplied to the measuring space 10 is eliminated and would only have to be checked at certain intervals in a random manner.

The ultrapure water can, however, also be introduced into the measuring space 10 at intervals (stopped-flow method), it remaining in the measuring space 10 for a predetermined period of time and being drained after this period. Then water is added again. The ultrapure water leaving the measuring room, i.e. the water enriched with hydrogen carbonate ions is fed to the mixed bed ion exchanger 5 after the conductivity measurement, in which it is regenerated and used again for the process.

For the analysis of ultrapure water samples where a very precise determination of the TOC content is necessary and inorganic compounds do not have to be expected, the removal of inorganic African connections are completely eliminated. In the case of more contaminated sample solutions in which inorganic substances have to be expected, removal of these by a mixed bed ion exchanger 1 is provided.

Claims

claims

1. A method for determining the total organically bound carbon (TOC) in aqueous samples, in which organic compounds are oxidized to carbon dioxide, characterized in that the carbon dioxide-containing samples are passed through an electrodialysis unit in which HC0 ₃ ^" ions and H ⁺ -Ions are generated, which pass through appropriate exchange membrane into a measuring chamber rinsed with ultrapure water and that the conductivity of the ultrapure water before

Reached in the measuring room and after leaving the measuring room is measured and the TOC content is determined from the measured conductivity values.

2. The method according to claim 1, characterized in that the ultrapure water is passed continuously through the measuring room.

3. The method according to claim 1, characterized in that the ultrapure water is passed in the stopped-flow method through the measuring room.

4. The method according to any one of claims 1 to 3, characterized in that the temperature of the

Measuring medium ultrapure water is measured before entering and after leaving the measuring room and is taken into account when determining the TOC content.

5. The method according to any one of claims 1 to 4, characterized in that the organic compounds are oxidized by UV radiation.

6. The method according to claim 5, characterized in that the oxidation is carried out catalytically.

7. The method according to any one of claims 1 to 6, characterized in that the used measuring medium ultrapure water is regenerated with the aid of an ion exchanger.

8. The method according to any one of claims 1 to 7, characterized in that before the oxidation of the organic compounds, inorganic carbons and optionally other organic compounds are preferably removed by ion exchange.

9. Device for determining the total organically bound carbon (TOC) in aqueous samples with a UV reactor (2) for irradiating and oxidizing the samples, characterized in that the UV reactor (2) is followed by an electrodialysis unit (3) which has a cathode space (6) with an anion exchange medium, an anode space (8) with a cation exchange medium and a measuring space (10), an anion exchange membrane (11) between cathode space (6) and measuring space (10) and between anode space (8) and Measuring space (10) a cation exchange membrane (12) are provided and is guided through the measuring space (10) ultrapure water and that a measuring device (17) for measuring the Conductivity of the ultrapure water before and after the measuring space (10) and an evaluation unit (4) for determining the TOC content using the measured values supplied by the measuring device (17) are provided.

10. The device according to claim 9, characterized in that a control device for controlling the supply and discharge of the ultrapure water into and out of the measuring space (10) is provided in a continuous or discontinuous manner.

11. The device according to claim 9 or claim 10, characterized in that a temperature measuring device for measuring the temperature of the

Ultrapure water is provided at the respective location of the conductivity measurement.

12. The device according to one of claims 9 to 11, characterized in that an ion exchanger

(5) is provided for the regeneration of the ultrapure water used.

13. Device according to one of claims 9 to 12, characterized in that an ion exchange unit (1) for removing inorganic carbon contained in the aqueous samples and optionally other inorganic compounds is connected upstream of the UV reactor (2).