EP1989539A1

EP1989539A1 - Gas sensor

Info

Publication number: EP1989539A1
Application number: EP07703682A
Authority: EP
Inventors: Ralf Liedtke
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2006-02-22
Filing date: 2007-01-08
Publication date: 2008-11-12
Also published as: DE102006008227A1; WO2007096203A1

Abstract

The present invention relates to a gas sensor (1) for determining a hydrogen-containing gas component and/or its concentration in a measurement gas, in particular for determining NH3, said sensor comprising two electrodes (3, 4) which are connected, such that they conduct protons, by means of a proton conductor (2), wherein a diffusion barrier (8) is arranged between a sensor region (7) which is to be exposed to the measurement gas and a first electrode (3) which is catalytically active with respect to cleaving of the hydrogen-containing gas component. The gas sensor is distinguished by the fact that the proton conductor (2) is connected to the two electrodes (3, 4) as a hydrogen ion pump cell (5, 15).

Description

description

title

gas sensor

The present invention relates to a gas sensor for determining a hydrogen-containing gas component and / or its concentration in a measuring gas, according to the preamble of claim 1.

State of the art

EP 0 693 180 B1 discloses an ammonia sensor which operates on an amperometric basis, wherein a membrane permeable to ammonia seals off the sensor to form a sample gas sample. The electrolyte contains a metal ion which is not oxidizable by atmospheric oxygen in aqueous solution and which forms a complex, oxygen-oxidizable metal ion with ammonia. This sensor is designed for room temperature and / or aqueous solutions. Its field of application is accordingly limited.

WO 01/48466 A2 discloses a sensor element of a gas sensor for determining the concentration of hydrogen present in a gas mixture or of hydrogen-containing gas components such as ammonia or hydrocarbons. In this case, on the basis of a proton-conducting solid electrolyte, an emf caused by different hydrogen or proton concentration at two measuring or reference electrodes is determined by measuring the applied electrical voltage in the so-called "Nernst cell" operating mode. Purpose and advantages of the present invention

The present invention is based on the object to improve a gas sensor for the determination of hydrogen-containing gas components in a sample gas, in particular NH3 shares, according to the manner outlined in the introduction.

This object is solved by the features of claim 1. In the dependent claims advantageous and expedient developments of the invention are given.

Accordingly, the invention relates to a gas sensor for determining a hydrogen-containing gas component and / or its concentration in a measurement gas, in particular for the determination of NH ₃ , comprising two protons conductively connected by a proton conductor electrodes, wherein between a measurement gas auszusetzenden sensor area and a first, with respect to a Splitting the hydrogen-containing gas component catalytically active electrode is disposed a diffusion barrier. The gas sensor is characterized in that the proton conductor is connected to the two electrodes as a hydrogen ion pumping cell.

A pump cell is understood as meaning an amperometrically operated electrolyte contacted via two electrodes. That is, at the two electrodes is a potential difference, and caused by the ion migration through the electrolyte electric current is z. B. detected as a measure of the concentration of hydrogen in the sample gas. The same applies of course to a proton conductor.

By means of an electric current flowing between the two electrodes, a very precise quantization of a hydrogen-ion current flowing through the hydrogen proton conductor is possible and thus an indirect determination of NH ₃ content in the sample gas.

In one possible embodiment, the hydrogen proton conductor formed as a solid may be composed of barium zirconate, in particular of doped barium zirconate. The construction of such a gas sensor can be carried out, for example, in the form of a planar sensor element. As a basic ceramic, for example, an yttrium-stabilized zirconia

(YSZ). The diffusion barrier serves as a gas resistance between the sample gas to be tested for specific proportions and / or concentrations and a sample gas sample chamber. It delimits the sample gas sample chamber from the sensor area to be exposed to the sample gas. In this sensor area, it may be z. B. may be an opening on one side of the sensor.

The so-called "hydrogen pump" formed from the two electrodes and the hydrogen proton conductor pumps out the hydrogen (H) formed in the splitting of ammonia (NH ₃ ) in ionized form (H ⁺ ) from the sample gas sample chamber For example, back to the room in which the sample gas to be tested is located, but it would also be conceivable to pump it off in an area which is separate from this room.

To support the splitting of the NH ₃ into its constituents, the use of a catalyst is furthermore proposed, which is particularly advantageously integrated into the first inner electrode arranged in the sample gas sample chamber. For this purpose, this first electrode may be made of a suitably suitable material, for example of platinum, in particular of pure platinum. Thus, it is possible to convert the total hydrogen content (H) of the gas component to be determined, in particular of NH3 for the evaluation of the measurement result into a hydrogen ion current and quantitatively by detecting the current flowing between the two electrodes electric current determine.

A first possible source of error for determining the concentration of the hydrogen fraction in a sensor constructed in this way can be eliminated by providing a first oxygen ion pumping cell, preferably arranged close to the diffusion barrier in the sample gas sample chamber. This ensures the removal of existing in the sample gas, free oxygen molecules, which could otherwise enter into a measurement falsifying binding with hydrogen or would usually. For pumping out these oxygen ions from the sample gas sample chamber can, for. B. serving as a carrier body, ceramic solid electrolyte is provided with two electrodes and acted upon by a corresponding electrical voltage.

For pumping the hydrogen ion stream out of the sample gas sample chamber, by contrast, a voltage source can be provided by means of which a pumping voltage (Up) can be applied at least during the measurement process between the two electrodes of the hydrogen ion pump. This pumping voltage is preferably designed so that it is selectively parameterized for the splitting of the hydrogen-containing gas component, in particular NH ₃ , into hydrogen (H) + one or more complementary components, such as nitrogen (N), at the first electrode.

Furthermore, it may preferably be parameterized so that it does not cause splitting of water (H ₂ O) also present in the sample gas sample in the form of water vapor into oxygen (O) and hydrogen (H ₂ ). Thus, by correspondingly suitable voltage values, significant reductions of otherwise occurring measurement errors can be effected.

Regardless of this pumping voltage, however, in the sample gas sample chamber located in the sample gas sample splits of existing water (H ₂ O) in (0 + 2H) instead. In particular, at high operating temperatures of the gas sensor, as this z. B. is the case when used in exhaust systems, such reactions may occur due to the targeted for optimum effect of the hydrogen pump, catalytic effect of the respective inner electrode heaped. The thereby released from the water (H ₂ O) released hydrogen components (2H) therefore forcibly move through the hydrogen pump and thus distort the measurement result by increasing the corresponding amount of the current flowing between the two electrodes of the hydrogen pump electric current.

In order to correct such measurement errors, due to the spatially limited spatial extent of the oxygen components (O) split off from the water (H ₂ O), a spatial allocation of a second oxygen pump to the inner electrode of the hydrogen pump can advantageously also be provided. Thus, these by the splitting of the water (H ₂ O) released oxygen fractions (0) by pumping over the Sauerstoffionenleitenden

Solid electrolyte of yttrium stabilized zirconia by means of the two associated with him two electrodes, inner and outer, are quantified by the resulting ion current or the corresponding electrode current exactly. But this again is an exact quantification of the complementary hydrogen ion current or the associated electron flow to the hydrogen ion pump possible.

By deducting the corresponding proportion of electron current from the decomposition of water from the total, measured by the hydrogen pump current, so now the split off of ammonia (NH ₃ ) share remains as a double-adjusted and thus extremely accurate measurement result. This applies in particular if, in contrast to the internal electrode assigned to the hydrogen pump, the internal electrodes assigned to the two oxygen pumps have only little or even no catalytic properties with regard to splitting NH ₃ exhibit. For example, a mixture of platinum (Pt) with about 0.5% of gold (Au) or of a mixture of palladium (Pd) with about 5% of gold (Au) may be used as the material.

embodiment

The invention will be explained in more detail with reference to the drawing and the description below. Accordingly, the attached figure shows a schematic cross section through a gas sensor for determining a hydrogen-containing gas component and / or their concentration in a measurement gas, in particular for the determination of NH ₃ .

In detail, the attached figure shows a schematic cross section through a gas sensor 1. To detect a hydrogen-containing gas component or its concentration, it is equipped with a proton conductor 2, which can be connected via two electrodes 3, 4 to a voltage source 5. In order to separate a sample gas sample chamber 6 from a sensor region 7 to be exposed to the sample gas, a diffusion barrier 8 is provided. It provides a gas resistance through which the sample gas must diffuse into the sample gas sample chamber 6. Optionally, this diffusion barrier may have a selective filtering effect, so that only certain gas fractions can pass through it. The electrode 3 arranged in the interior of the sample gas sample chamber 6 is preferably catalytically active with respect to a splitting of a hydrogen-containing gas component. According to the invention, the proton conductor 2 is connected to the two electrodes 3, 4 as a hydrogen ion pumping cell 9.

Ceramic bodies (10, 11, 12), preferably yttrium-stabilized zirconia, are provided as carrier bodies for the sensor 1.

In the lower layer 12, a heating element 13 is inside an insulation 14 embedded. By means of this heating element, the sensor can be adjusted to a specific operating temperature.

The hydrogen ion pumping cell 9 according to the invention is arranged in the plane of the layer 11 together with the sample gas sample chamber 6 and the diffusion barrier 8. The sensor region 7 to be exposed to the measurement gas is in this case designed, for example, in the end region of the sensor 1. Through it, the test gas to be tested can diffuse across the diffusion barrier 8 into the sample gas sample chamber 6.

According to the invention, an electric current flowing through the two electrodes 3, 4 is detected as a measure of the concentration of hydrogen ions of the gas component to be detected by the ammeter 15 shown here by way of example.

Since, due to oxygen molecules present in the measurement gas, a migration of free hydrogen ions occurring at the catalytically active electrode 3 would falsify the measurement result, a first oxygen-ion pump cell is provided for eliminating such measurement errors. It comprises the ceramic solid-state electrolyte 17 formed as a carrier element as well as the two electrodes 18, 19. The outer electrode 18 is additionally coated with a protective layer 20. For operation of the oxygen-ion pumping cell 16, a current or voltage source 21 is further provided.

Since high levels of gaseous water (H ₂ O) are also present in sample gases, in particular in exhaust gases, a splitting of these water parts into hydrogen (2H) and oxygen (O) would additionally falsify the measurement result at the hydrogen ion pump cell 9 Hydrogen content in the sample gas sample chamber 6 effect. Since these splitting processes can not be reliably avoided, the present invention therefore additionally proposes a second oxygen pumping cell 23 spatially or functionally associated with the sample gas sampling chamber. This is how the Oxygen Ionenpumpzelle 21, an inner electrode 23 and an outer electrode 24, which are conductively connected to each other by an electrolyte oxygen ions. Here, in this preferred embodiment, this oxygen-ion conducting electrolyte is again produced by the ceramic body in the form of a yttrium-stabilized zirconia, which is designed as a carrier body. For mechanical and / or chemical protection of the outer electrode 24, a protective layer 26 is also shown here by way of example.

In order to avoid distortions of the measurement result at the hydrogen ion pump cell 9 due to additionally detected by them hydrogen ions resulting from the splitting of water present in the sample gas, the inner electrode 23 of the second oxygen-ion pumping cell 22 in the vicinity of the inner Electrode 3 of the hydrogen ion pumping cell 9 is arranged. Here in the exemplary embodiment, these two electrodes face each other in the sample gas sample chamber 6. As a result, all the oxygen atoms released by the splitting of the water (H ₂ O) into (2H) plus (O) can be quantified. This is done by means of the electrons of the corresponding electric current flowing through the amperometer 28 shown here by way of example. Thus, the measurement error resulting from the splitting of water is known and can be reliably corrected by a corresponding subtraction on the measurement result of the hydrogen ion pump cell. What remains is only the hydrogen ion current, which results from the splitting of the measurement gas component to be detected, such as NH ₃ .

In order to be able to have a positive effect on the measurement result in advance of the measurement result evaluation, the present invention further provides that the two inner electrodes 19, 23 of the two oxygen-ion pumping cells 16, 22 are constructed from materials which as far as possible do not split the water into Support or cause hydrogen and oxygen fractions. You can do this, for example, from a Blend of platinum (Pt) with about 0.5% gold (Au) or consist of a mixture of palladium (Pd) with about 5, 0% gold (Au).

By contrast, the inner electrode 3 of the hydrogen ion pump cell can consist, for example, of pure platinum (Pt), which, as is known, has very good catalytic properties with regard to a splitting of hydrogen-containing gas components. The proton conductor 2 may itself be composed of proportions of barium zirconate, in particular of doped barium zirconate. In the present example, this barium zirconate is embedded in an insulation 29 in the form of aluminum oxide (Al 2 O 3).

Claims

claims

1. A gas sensor (1) for determining a hydrogen-containing gas component and / or its concentration in a measurement gas, in particular for the determination of NH3, comprising two by a proton conductor (2) protons electrically connected electrodes (3, 4), wherein between an exposed to the measurement gas Sensor region (7) and a first, with respect to a decomposition of the hydrogen-containing gas component catalytically active electrode (3) a diffusion barrier (8) is arranged, characterized in that the proton conductor (2) with the two electrodes (3, 4) as a hydrogen ion pumping cell (9) is connected.

2. Gas sensor according to claim 1, characterized in that between the two electrodes (3, 4) flowing electric current is a measure of the concentration of hydrogen ions of the gas component to be detected.

3. Gas sensor according to claim 1 or 2, characterized in that the diffusion barrier (8) has a measuring gas sample chamber

(6) delimits from the sensor area (7) to be exposed to the measurement gas.

4. Gas sensor according to claim 1, 2 or 3, characterized in that a first, the sample gas sample chamber

(6) associated oxygen ion pumping cell (16) is provided.

5. Gas sensor according to one of the preceding claims, characterized in that an at least during the measuring operation at the hydrogen ion pumping cell (9) applied electrical pumping voltage selectively for the splitting of the hydrogen-containing gas component at the first electrode (3), in particular NH3, in hydrogen (H) + one or more complementary components, such as nitrogen (N) is parametrized.

6. Gas sensor according to one of the preceding claims, characterized in that a second, the sample gas sample chamber

(6) spatially or functionally associated oxygen ion pumping cell (22) is provided.

7. Gas sensor according to one of the preceding claims, characterized in that an electrode (23) of the second oxygen ion pumping cell (22) in the Meßgasprobenkammer (6) spatially or functionally associated with the first electrode (3) of the hydrogen ion pumping cell (7) is arranged.

8. Gas sensor according to one of the preceding claims, characterized in that in the Meßgasprobenkammer (6) arranged electrode (19, 23) of the first and / or the second oxygen ion pumping cell (16, 22) of a material with little to no catalytic Characteristics with respect to a decomposition of hydrogen-containing gas components is formed.

9. Gas sensor according to one of the preceding claims, characterized in that the electrode (19, 23) of the first and / or the second oxygen ion pumping cell (16, 22) of a mixture of platinum (Pt) with about 0, 5% - Shares of gold (Au) consists, or of a mixture of palladium

(Pd) with about 5. 0% gold (Au).

10. Gas sensor according to one of the preceding claims, characterized in that the hydrogen proton conductor (2) comprises proportions of barium zirconate.

11. Gas sensor according to one of the preceding claims, characterized in that the first electrode (3) made of platinum (Pt) is prepared.