Abstract:
An electrochemical sensor for ascertaining gas concentrations in gases, particularly in exhaust gases of combustion engines, includes an oxygen-ion-conductive solid electrolyte which is provided with electrode layers arranged at a distance from one another and with at least one resistance heating element that is separated from the solid electrolyte by an electrical insulating layer, a foil binder layer being provided between the electrical insulating layer and the solid electrolyte. At least one electron-conductive intermediate layer is provided between the electrode-side electrical insulating layer and the adjacent solid electrolyte.

Description:
BACKGROUND INFORMATION 
     In the electrochemical sensor described in German Pat. No. 31 20 159, the danger exists that during the operation of the heating element, particularly if there is insufficient insulation between the heating element and the oxygen-ion-conductive solid electrolytes which, for example, can be made of yttrium-stabilized ZrO 2  (YSZ ceramic), leakage currents will occur which electrically couple the sensor cell to the heating element. First of all, such an electrical coupling reduces the service life of the heater, since reduction effects occur in the active ceramics, and secondly, the measuring signals emitted by the sensor are increasingly and permanently invalidated. Given continuous occurrence, the leakage currents lead to a local blackening of the sensor. In addition, the thin heating lines of the resistance heating element can burn through due to the local heating. In the case of the known sensor, a further disadvantageous effect occurs because of the interspersing of interference signals from the heating element, operated with pulsed voltage, into the probe signal, whereby the measuring accuracy drops because of the reduced signal-to-interference ratio. 
     SUMMARY OF THE INVENTION 
     An object of the present invention is to prevent an electrical coupling from the solid-electrolyte sections of the sensor to the heating element during its operation. Furthermore, the intention is to construct a sensor according to the present invention in such a way that blackening no longer occurs during the check for leakage current. Moreover, a sensor of the present invention is to be constructed in a manner that the service life of the heating element is extended. In addition, a sensor according to the present invention should be able to deliver a stable measuring signal over its service life. A sensor of the present invention should also be constructed so that no interference signals from the heating element are interspersed into the measuring-active ceramics, and thus into the sensor signal. A further intention is that the sensor of the present invention be so designed that the accuracy of the measuring signal is improved. 
     In an electrochemical sensor, designed according to the present invention, for ascertaining gas concentrations in gases, particularly in exhaust gases of internal combustion engines, having an oxygen-ion-conductive solid electrolyte which is provided with electrode layers arranged at a distance from one another and with at least one resistance heating element that is separated from the solid electrolyte by an electrical insulating layer, at least one foil binder layer being provided between the electrical insulating layer(s) and the solid electrolyte, at least one electron-conductive intermediate layer is provided between the electron-side electrical insulating layer and the adjacent solid electrolyte. 
     In one preferred specific embodiment, the electrochemical sensor of the present invention has a thin electron-conductive metal layer at least above the resistance heating element. This metal layer can either be imprinted flat-spread as a platinum-containing paste at least over the hot region of the sensor, or else can be applied in the form of a platinum lattice structure at least over the hot region of the sensor. Alternatively, the platinum lattice structure or the imprinted layer made of platinum paste can also lie over the entire surface, i.e., over the hot regions and the leads of the resistance heating element. 
     The platinum lattice structure can have lattice bars running at right angles, i.e., parallel to the edges of the sensor, or else running diagonally at a specific angle. 
     In one specific embodiment, the electron-conductive intermediate layer, such as the platinum lattice or a platinum mesh, can lie directly over the electrical insulating layer. Alternatively, the electron-conductive intermediate layer, i.e., particularly the platinum lattice or the platinum mesh, can replace or so modify one of the foil binder layers in the sensor that this/these foil binder layer(s) have sufficient electron conductivity. At the same time, the thermal conductivity of the construction counteracts local overheating of the heater. 
     To reduce or screen off the interference signals coupled in from the resistance heating element, the electron-conductive intermediate layer or intermediate layers, such as the platinum lattice, can be electrically connected to a defined potential, in particular to earth (ground) potential in the sensor. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows schematically and in section a layer construction of a preferred exemplary embodiment of an electrochemical sensor according to the present invention. 
     FIG. 2A shows schematically and in the form of a plan view, a first embodiment of a metallic electron-conductive intermediate layer according to the present invention. 
     FIG. 2B shows a second embodiment. 
     FIG. 2C shows a third embodiment. 
     FIG. 2D shows a fourth embodiment. 
     FIG. 2E shows a fifth embodiment. 
     FIG. 2F shows a sixth embodiment. 
     FIG. 2G shows a seventh embodiment. 
    
    
     DETAILED DESCRIPTION 
     FIG. 1 shows schematically a cross-section through a segment of an electrochemical sensor which embodies a preferred exemplary embodiment of the present invention. It should be noted that the sectional view illustrated in FIG. 1 represents merely the sensor layers located around the heating region made up essentially of a heating foil  1 , a heating meander  11  made of electrical resistance material, and electrical insulating, layers  4  (to the top) and  3  (to the bottom) situated around it. Specifically, the electrochemical sensor shown in FIG. 1 is a planar oxygen probe as is used, for example, in the technology of catalytic exhaust emission control of internal combustion engines under the technical designation “planar broad-band lambda probe”. The heater, composed of heating meander  11 , upper electro-insulating layer  4  and lower electro-insulating layer  3 , is mounted with the aid of heating foil  1  on a first solid electrolyte whose details are not further described. 
     The heater is sealed off on both sides by sealing frame  2  made of ZrO 2 . Situated over the heater is a foil binder layer  5 , and above that, a reference-channel foil  9  which surrounds a reference-gas channel  12  with a reference electrode  16 . Above reference-channel foil  9  and reference-gas channel  12  is a Nernst foil  10 , made of a solid-electrolyte body, which is possibly also provided with a pump cell (not shown). Lying on Nernst foil  10  is a measuring electrode  17  protected by a protective layer  18 . It should be mentioned that insulating layers  3  and  4  are made of a ceramic material, namely, a mixture of Al 2 O 3 +SiO 2 +BaCO 3 . Heating meander  11  is made of Pt+AI 2 O 3 , and the foil binder is made of ZrO 2 . 
     In the exemplary embodiment shown in FIG. 1, situated above upper insulating layer  4 , directly below foil binder layer  5 , is an electron-conductive intermediate layer  13  made of metallic material, preferably in the form of a platinum lattice or mesh. A further electron-conductive intermediate layer  14  can lie between heater foil  1  and lower insulating layer  3 . However, preferably only the upper electron-conductive intermediate layer  13  is provided. 
     This platinum lattice or mesh can have one of the structures shown in FIGS. 2A through 2D, and according to FIGS. 2A and 2C can either cover the hot region and the leads to the heating element, or only the hot region of the heating element according to FIGS. 2B and 2D. 
     In a specific embodiment not shown in FIG. 1, electron-conductive intermediate layers  13 ,  14  are imprinted layers made of a platinum paste and have one of the structures shown in FIGS. 2E-2G. 
     Deviating from the specific embodiment shown in FIG. 1, the electron-conductive intermediate layer or intermediate layers  13 ,  14  can have the following variants: 
     only one, preferably upper electron-conductive intermediate layer  13  is provided; 
     foil binder layer  5  can be replaced by such an electron-conductive intermediate layer; 
     the electron-conductive intermediate layer can also be combined in each of these configurations with an ion-conductive intermediate layer, so that both electron and ion conduction occurs in this layer. It should further be mentioned that, in particular to prevent interference signals from being interspersed into the measuring signal, each of electron-conductive intermediate layers  13 ,  14  in any configuration can be connected to a defined potential, preferably to earth potential, within the sensor. 
     In the following, various preferred and possible structure variants of a platinum intermediate layer  13  are clarified on the basis of the plan views in FIGS. 2A-2G. 
     FIG. 2A shows a specific embodiment in which a right-angled platinum lattice structure  13   a  is placed straight and completely over the heater and its leads. Depending upon the construction, the lattice dimensions can vary from coarse to fine, i.e. approximately between lattice constants (from lattice iine to lattice line) of 0.7 mm to 0.2 mm. Not only quadratic, but also rectangular patterns are possible, in which the lattice constant in the vertical direction differs from the lattice constant in the horizontal direction. 
     The variant of a platinum lattice  13   b  shown in FIG. 2B likewise has a right-angled, straight lattice pattern. However, platinum lattice  13   b  covers only the hot region of the sensor element. The lattice dimensions can be identical to those mentioned for Figure 
     FIG. 2C shows a further structure variant, in which the platinum lattice structure  13   c  is arranged at a specific angle to the sensor element and is placed completely over the heater and its leads. It can be seen that the structure variant shown in FIG. 2C likewise forms a right-angled lattice. However, this is not necessarily so. Instead of a right-angled or quadratic lattice profile, the lattice lines can also assume an angle deviating from 90° relative to each other. Thus, both rectangular, quadratic, diamond-shaped, and even round and elliptical lattice patterns are possible. 
     The pattern variant shown in FIG. 2D resembles that in FIG. 2C, however, in this case, lattice  13   d  covers only the hot region of the sensor element. 
     In the case of the variants shown in FIGS. 2E,  2 F and  2 G, electron-conductive intermediate layers  13   e ,  13   f  and  13   g  do not form a lattice or mesh structure as in FIGS. 2A-2D, but rather are applied in the form of a full surface or in the form of broader.platinum strips over the layers of the resistance heating element and its leads. In FIG. 2E, electron-conductive intermediate layer  13   e  completely covers the heater and the leads; in FIG. 2F, the full surface of electron-conductive intermediate layer  13   f  is placed only over the hot region of the sensor element; and finally, electron-conductive intermediate layer  13   g  according to FIG. 2G covers the resistance heating layers of the heater and its leads, so that the resistance layers of the heater are overlapped by electron-conductive intermediate layer  13   g.    
     Common to all the embodiment variants of electron-conductive intermediate layer or intermediate layers  13   a - 13   g  shown in FIGS. 2A-2G is that they prevent an electrical coupling from the sensor cell to the heater, thus preventing leakage currents. Blackening is avoided during the leakage-current check. The service life of the heater, and thus of the electrochemical sensor according to the present invention, is extended (longer at least by the factor 5-10). Service life is also extended in the case of sensors without edge grinding (polishing). Reduction effects in the measuring-active ceramic bodies, and thus a change in the sensor characteristics, are prevented. In addition, the platinum functions as a catalyst and converts an electron flow occurring in the insulation into an O 2 -ion flow in the ZrO 2 -body, and in this manner decreases the reduction of ZrO 2 . The electron-conductive intermediate layer or layers also prevent interference signals from being interspersed into the measuring signal, and thus increase its signal-to-interference ratio. In addition, the specific embodiments according to FIGS. 2A-2D, having a lattice net-like pattern of the electron-conductive intermediate layer(s), save on material, i.e., lower costs for raw materials arise during the production of a lattice-type or net-like electron-conductive intermediate layer than when manufacturing a massive platinum intermediate layer.