DE19755506A1 - Electrochemical sensor with an open housing - Google Patents

Description

The invention relates to an electrochemical sensor according to the preamble of Claim 1.

A generic electrochemical sensor is for example in the EP 0298 570 B1 has been described and is used for determining the concentration of gases in the surrounding atmosphere.

An essential feature of the electrochemical sensors used so far consists of equipping them with one for the diffusion of the gas to be measured permeable membrane, which with the electrolyte used in Liquid connection is established. In case of using strongly alkaline or certain organic electrolytes are also disadvantageous in that these electrolytes inadvertently emerge from the sensor housing and damage to the sensor and in its environment.

Furthermore, the known membranes have the disadvantage that they are strong adsorbing gases are trapped when passing through these membranes and therefore can only be measured with very low sensitivity. Another disadvantage of the previously known electrochemical sensors results if, for the detection of special gases, such as HCI, HF or Hydrazine special liquid electrolytes should be used due to the characteristic electrochemical detection reactions gases or vapors form, which must be removed from the sensor, because otherwise they generate unwanted signal currents.

The object of the invention is an electrochemical sensor for the To provide concentration measurement of strongly adsorbing gases for their electrochemical detection of liquid electrolytes can be used which is disruptive Form gases or vapors as electrochemical secondary products,  which have to be removed from the sensor.

The solution to the problem is obtained for an electrochemical sensor The type mentioned at the outset with the characterizing features of claim 1. The subclaims define advantageous developments and refinements of the electrochemical sensor according to claim 1.

A major advantage of the sensor according to the invention is on the one hand that from the raised and / or planar arrangement of the electrodes Precious metal, especially platinum, on the electrode carrier in the form of a welded mesh or in the form of sputtered or powder Sintered flat pattern faster and more sensitive sensor signals can be achieved. On the other hand, the lack of a gas permeable membrane direct access of the gases to be detected Electrodes possible and thus increases the sensitivity. Eventually through the the electrolyte reservoir, preferably in the gas flow direction downstream adsorbent reservoir the use of such special liquid electrolytes possible, the corrosive, toxic or unwanted gases or Form vapors, which are adsorptively bound in the adsorbent reservoir. A typical example are liquid electrolytes containing bromide or bromate, which are used to detect HCI. In such an electrolyte Chemical reactions produce bromine in the adsorbent reservoir can be adsorptively bound to activated carbon, for example.

In the following an embodiment of the invention by means of the figure explained, which represents a longitudinal section through a sensor according to the invention and schematically reproduces its structure.

The actual sensor structure is located in a preferably pot-shaped, rotationally symmetrical housing 1 made from a gas-impermeable material, for example from a plastic, in the region of the electrodes with the electrode carrier 4 .

A measuring electrode 2 and a counter electrode 3 are applied to a porous electrode carrier 4 . Measuring electrode 2 and counter electrode 3 are preferably made of platinum and are welded flat in the form of electrically contacted networks on preferably raised portions of the electrode carrier 4 . The flat and preferably raised arrangement of the electrodes on the electrode carrier 4 makes the measurement signals faster and more sensitive. Alternatively, the electrodes can be printed, sintered on, sputtered on, or welded onto the electrode carrier 4 from powder. This arrangement and design of the electrodes surprisingly led to faster and more sensitive measurement signals. It is particularly advantageous if the electrodes are coated with a hydrophilic coating with a layer thickness of approximately one micron in order to enable uniform wetting with the liquid electrolyte. The hydrophilic coating can consist, for example, of a material containing SiO ₂ (silica).

Alternatively, it is possible to mount the counter electrode 3 and, if appropriate, an additional reference electrode in the electrolyte reservoir 6 . In this case, only the measuring electrode 2 is located on the porous electrode carrier 4. The electrode carrier 4 is soaked with electrolyte. The electrode carrier 4 is in fluid communication with the electrolyte reservoir 6 via the porous wick 5 . The electrolyte reservoir 6 contains a porous material loaded with electrolytes by means of capillaries, in particular a fleece made of glass fibers, polypropylene or polyethylene. The electrode carrier 4 has finer capillaries than the material in the electrolyte reservoir 6 , so that the electrolyte migrates to the electrode carrier 4 due to the stronger capillary forces.

If the ambient humidity is high, the electrolyte absorbs water and the electrolyte volume increases. The enlarged electrolyte volume is taken up by the electrolyte reservoir 6 .

If the surrounding atmosphere is dry, the electrolyte loses water. However, the electrode carrier 4 does not dry out, but takes up so much electrolyte from the electrolyte reservoir 6 that its pore system is always filled with electrolyte. The sensor has at least one pressure compensation opening 7 , which ensures that the internal pressure of the sensor is always equal to the pressure in the ambient atmosphere. The electrolyte cannot be pushed out of the capillary system by pressure changes in the surrounding atmosphere.

The adsorbent reservoir 9 is in gas flow connection with the electrolyte reservoir 6 via gas-permeable but electrolyte-impermeable porous disks 8 and on the other hand in gas flow connection with the ambient atmosphere via the at least one pressure compensation opening 7 .

As an alternative to the illustration in the figure, the adsorbent reservoir 9 can be arranged in the electrolyte reservoir 6 . In this case, the adsorbent, that is activated carbon, aluminum oxide, silica gel or zeolite, is in a gas-permeable, but electrolyte-impermeable sleeve made in particular of PTFE, polyethylene or also polypropylene.

For example, if a gas sensor is designed to detect HCI, the suitable electrolyte, an electrolyte containing bromate or bromide is used become. Arises in the course of the electrochemical detection reaction unwanted bromine vapors or gases generated by the adsorbent be intercepted.

The limiting components of the housing 1 , 10 , 11 consist of a gas and electrolyte impermeable material, in particular of a plastic.

Claims (11)

1. Electrochemical sensor with a housing made of a gas-impermeable material, an electrode carrier with electrodes arranged in the housing and an electrolyte reservoir, the electrolyte reservoir being in fluid communication with the electrode carrier by means of a wick, characterized in that
that one or more electrodes are arranged flat and / or raised on the porous electrode carrier ( 4 ) and in the open area of the housing ( 1 ) are exposed to the ambient atmosphere without the interposition of a membrane, and
that the electrolyte reservoir ( 6 ) is in gas flow connection with the ambient atmosphere. 2. Electrochemical sensor according to claim 1, characterized in that the electrolyte reservoir ( 6 ) is also in gas flow connection with an adsorbent reservoir ( 9 ). 3. Electrochemical sensor according to at least one of claims 1 or 2, characterized in that the counter electrode ( 3 ) and / or an additional reference electrode are arranged in the electrolyte reservoir ( 6 ). 4. Electrochemical sensor according to at least one of claims 1 to 3, characterized in that the one or more, arranged on the electrode carrier ( 4 ) electrodes in the form of electrically contacted networks, wires, sputtered, printed, welded or sintered metal layers, preferably from Platinum or from another precious metal, are formed. 5. Electrochemical sensor according to at least one of claims 1 to 4, characterized in that the one or more electrodes are coated with a micrometer-thin coating of an absorbent, hydrophilic material, in particular of silica (SiO ₂ ). 6. Electrochemical sensor according to at least one of claims 2 to 5, characterized in that the adsorbent reservoir ( 9 ) contains one or more of the adsorbents activated carbon, aluminum oxide, silica gel, zeolites. 7. Electrochemical sensor according to at least one of claims 2 to 6, characterized in that the adsorbent reservoir ( 9 ) and / or the electrolyte reservoir ( 6 ) by means of one or more pressure compensation openings ( 7 ) are in gas flow connection with the ambient atmosphere in front of the electrodes. 8. Electrochemical sensor according to at least one of claims 1 to 7, characterized in that the electrolyte reservoir ( 6 ) contains a porous material loaded with an electrolyte, in particular a fleece made of glass fibers, polypropylene or polyethylene. 9. Electrochemical sensor according to at least one of claims 1 to 8, characterized in that the electrolyte reservoir ( 6 ) contains a bromide-containing electrolyte. 10. Electrochemical sensor according to at least one of claims 8 or 9, characterized in that the electrode carrier ( 4 ) has finer capillaries than that contained in the electrolyte reservoir ( 6 ), loaded with an electrolyte material, so that the electrolyte by means of stronger capillary forces to the electrode carrier ( 4th ) hikes. 11. Electrochemical sensor according to at least one of claims 2 to 9, characterized in that the adsorbent is located within a porous, gas-permeable, but not permeable to the electrolyte sleeve, in particular made of PTFE (polytetrafluoroethylene), polyethylene or polypropylene, which is in the electrolyte reservoir ( 6 ) is arranged.