DE102006002111A1 - Sensor element for gas sensors for determining concentration of particles in gas mixtures has heating element, which is placed inside sensor element in spatial manner between measuring arrangement and temperature measuring element - Google Patents

Abstract

The sensor element (10) has at least one measuring arrangement that is exposed to gas to be identified. A heating element (40) and a temperature measuring element (30) are integrated in the sensor element. The heating element is placed inside the sensor element in a spatial manner between measuring arrangement and temperature measuring element. Independent claims are also included for the following: (A) Method for operating sensor element; and (B) Use of sensor element.

Description

The The invention is based on a sensor element and a method for determination the concentration of particles in gas mixtures and their use according to the Generic term of the independent claims defined type.

in the Course of a tightening Environmental legislation is increasingly gaining exhaust aftertreatment systems Meaning, the filtration or elimination of in combustion gases existing soot particles enable. To the functionality such exhaust aftertreatment systems to check or monitor, sensors are needed with which even in long-term operation an accurate determination of the current be made possible in the combustion exhaust gas particle concentration can. About that In addition, by means of such sensors, a loading forecast, for example a diesel particulate filters provided in an exhaust system are enabled, to achieve a high system security and thus more cost-effective To be able to use filter materials.

From the US 6,634,210 B1 For example, a sensor for detecting substances in a fluid flow is known, which is designed on the basis of a ceramic multilayer substrate. It comprises two spaced-apart measuring electrodes, which are exposed to the combustion exhaust gas to be examined. If soot is deposited between the two measuring electrodes, a current flow between the measuring electrodes occurs when a voltage is applied to the measuring electrodes. A layered heating element makes it possible to free the electrodes or their surroundings by thermal means from deposited soot particles. The sensor further comprises a temperature measuring element with which the temperature of the sensor can be detected. The temperature measuring element is located within the composite layer of the sensor between the heating element and the measuring electrodes. A disadvantage of this design of the sensor is that the temperature determined via the temperature measuring element does not correspond to the temperature which prevails in the region of the measuring electrodes.

task The present invention is a sensor element for sensors and a method for determining the concentration of particles in gas mixtures that provide accurate temperature control allowed and yet inexpensive accomplished can be.

Advantages of invention

The Sensor element or the method with the characterizing features which has independent claims the advantage that the problem underlying the invention in solved in an advantageous manner. This is based in particular on the simple structure of the sensor element and that the heating element is spatially interposed within the sensor element a measuring arrangement and a temperature measuring element of the sensor element is arranged. In this case, in particular, a symmetrical arrangement of the temperature measuring element or measuring electrodes with respect to Position of the heating element within the sensor element or with respect to the large areas of the Sensor element provided.

Further advantageous embodiments the present sensor element or method for operating the same emerge from the dependent claims.

So it is advantageous if the measuring electrodes are preferably in one another toothed interdigital electrodes are executed, since in this way the electrical resistance or the electrical conductivity greater surface areas can be determined under defined conditions and thus the sensitivity and the goodness the measurement signals is significantly improved.

In a particularly advantageous embodiment of the present invention Invention, an evaluation device is provided, which is a change of determined between the measuring electrodes adjacent current flow and this as a measure of the particle concentration outputs.

Farther is advantageous if the measuring electrodes of the sensor element in the the same layer plane are arranged as the heating element and / or the Temperature measuring element, since thereby the structure of the sensor element can be significantly simplified.

The Sensor element or the method for operating the same is more advantageous Way suitable for monitoring the operation of a diesel engine or to check the functionality or the loading state of a particulate filter.

drawing

Two embodiments of the sensor element according to the invention are shown schematically simplified in the drawing and are explained in more detail in the following description. It shows 1 a sensor element according to a first embodiment in an exploded view and 2 a sensor element according to a second embodiment in a plan view.

description the embodiments

In 1 a basic structure of an embodiment of the present invention is shown. With 10 a ceramic sensor element is designated which serves to determine a particle concentration, such as, for example, the soot concentration, in a gas mixture surrounding the sensor element. The sensor element 10 For example, it includes a plurality of oxygen ion conductive solid electrolyte layers 11a . 11b and 11c , The solid electrolyte layers 11a and 11c are carried out as ceramic films and form a planar ceramic body. They consist of an oxygen ion-conducting solid electrolyte material, such as ZrO ₂ stabilized or partially stabilized with Y ₂ O ₃ .

The solid electrolyte layer 11b in contrast, by means of screen printing of a pasty ceramic material, for example on the solid electrolyte layer 11a generated. As a ceramic component of the pasty material preferably the same solid electrolyte material is used, from which also the solid electrolyte layers 11a . 11c consist.

Furthermore, the sensor element, for example, a plurality of electrically insulating ceramic layers 12a . 12b . 12c . 12d . 12e and 12f on. The layers 12a - 12f are also by screen printing of a pasty ceramic material, for example, on the solid electrolyte layers 11a . 11b . 11c generated. As a ceramic component of the pasty material, for example, barium-containing aluminum oxide is used, since this has a largely constant high electrical resistance even with thermal cycling over a long period of time. Alternatively, the use of ceria or the addition of other alkaline earth oxides is possible.

The integrated shape of the planar ceramic body of the sensor element 10 is laminated by laminating with the solid electrolyte layer 11b and with functional layers as well as the layers 12a - 12f printed ceramic films and subsequent sintering of the laminated structure in a conventional manner.

The sensor element 10 also has a ceramic heating element 40 on, which is designed in the form of an electrical resistance track and the heating of the sensor element 10 in particular to the temperature of the gas mixture to be determined or to burn off the on the large surfaces of the sensor element 10 Deposited soot particles serves. The resistor track is preferably made of a cermet material; preferably as a mixture of platinum or a platinum metal with ceramic portions, such as alumina. The resistance conductor track is furthermore preferably designed in the form of a meander and has plated-through holes at both ends 42 . 44 as well as electrical connections 46 . 48 on. By applying an appropriate heating voltage to the terminals 46 . 48 The resistance track can control the heating power of the heating element 40 be regulated accordingly.

On a large surface of the sensor element 10 are for example two measuring electrodes 14 . 16 applied, which are preferably formed as interdigitated interdigital electrodes. The use of interdigital electrodes as measuring electrodes 14 . 16 advantageously allows a particularly accurate determination of the electrical resistance or the electrical conductivity of the between the measuring electrodes 14 . 16 surface material. For contacting the measuring electrodes 14 . 16 are in the region of a gas mixture facing away from the end of the sensor element contact surfaces 18 . 20 intended. Here are the supply areas of the electrodes 14 . 16 preferably by a further, electrically insulating, ceramic layer 12f against the influences of the sensor element 10 shielded surrounding gas mixture.

On the with the measuring electrodes 14 . 16 provided large area of the sensor element 10 In addition, a porous layer, not shown for reasons of clarity may be provided, which the measuring electrodes 14 . 16 shielded in their interlocked region against direct contact with the gas mixture to be determined. The layer thickness of the porous layer is preferably greater than the layer thickness of the measuring electrodes 14 . 16 , The porous layer is preferably made open-porous, wherein the pore size is selected so that the particles to be determined in the gas mixture can diffuse into the pores of the porous layer. The pore size of the porous layer is preferably in a range of 2 to 10 microns. The porous layer is made of a ceramic material, preferably the material of the layer 12a is similar or corresponds to this and can be prepared by screen printing. The porosity of the porous layer can be adjusted accordingly by adding pore formers to the screen printing paste.

During operation of the sensor element 10 gets to the measuring electrodes 14 . 16 a voltage applied. Because the measuring electrodes 14 . 16 on the surface of the electrically insulating layer 12a are arranged, it comes first in wesentli no current flow between the measuring electrodes 14 . 16 ,

Contains one the sensor element 10 flowing gas mixture particles, in particular soot, so they store on the surface of the sensor element 10 from. Due to the open-pore structure of the porous layer, the particles diffuse through the porous layer into the immediate vicinity of the measuring electrodes 14 . 16 , Since soot has a certain electrical conductivity, it comes with sufficient loading of the surface of the sensor element 10 or the porous layer with soot to an increasing current flow between the measuring electrodes 14 . 16 which correlates with the extent of loading.

Will now contact the measuring electrodes 24 . 26 a preferably constant DC or AC voltage applied and that between the measuring electrodes 24 . 26 ascertained current flow, it can be concluded from the integral of the current flow over time on the deposited particle mass or on the current particle mass flow, in particular soot mass flow, and on the particle concentration in the gas mixture. With this measurement method, the concentration of all those particles in a gas mixture is detected, which determines the electrical conductivity of itself between the measuring electrodes 24 . 26 have a positive or negative influence on the ceramic material.

A another possibility is to determine the increase in current flow over time and from the quotient of current flow increase and time or from the differential quotient from current flow after the time to the deposited particle mass or to the current particle mass flow, in particular soot mass flow, and to close the particle concentration in the gas mixture. A Calculation of the particle concentration is based on the measured values possible, provided the flow rate the gas mixture is known. This or the volume flow of the gas mixture can be determined, for example, by means of a suitable further sensor.

In addition, the sensor element comprises 10 a temperature measuring element 30 , which is preferably designed in the form of an electrical resistance track. The resistance track is made, for example, of a similar or the same material as that of the resistance track of the heating element 40 , The resistance trace of the temperature measuring element 30 is preferably in the form of a meander, wherein one of the terminals of the resistor track preferably via the terminal 48 is grounded. Furthermore, the temperature measuring element 30 another electrical connection 32 on. By applying an appropriate voltage to the terminals 32 . 48 the resistance trace and by determining the electrical resistance thereof can be closed to the temperature of the sensor element. Alternatively, a temperature determination by means of thermocouples is possible. Another alternative or additional possibility of Tempraturmessung is the per se temperature-dependent conductivity of the between the resistance track of the temperature measuring element 32 and the measuring electrodes 24 . 26 to determine arranged ceramic body and close from its height to the temperature of the sensor element.

The by means of the measuring electrodes 14 . 16 certain electrical resistance of between the measuring electrodes 14 . 16 material is subject to a strong temperature dependence. In this respect, the most accurate determination possible is that in the area of the measuring electrodes 14 . 16 sensor temperature is an important prerequisite for obtaining usable measurement results. Because of spatial reasons, however, a temperature determination in the immediate area of the measuring electrodes 14 . 16 often can not be realized, the measuring electrodes 14 . 16 , the heating element 40 and the temperature measuring element 30 within the sensor element 10 spatially arranged so that the heating element 40 arranged in a layer plane that extends between the measuring electrodes 14 . 16 containing layer plane and the temperature measuring element 30 layer containing layer is located. In particular, when the measuring electrodes 14 . 16 and the temperature measuring element 30 while substantially the same distance with respect to the heating element 40 have, are indeed the measuring electrodes 14 . 16 and the temperature measuring element 30 in different areas of the sensor element 10 arranged, by a substantially comparable distance of the measuring electrodes 14 . 16 or the temperature element 30 from the heating element 40 however, it can be assumed that at the measuring electrodes 14 . 16 a comparable temperature prevails, as they of the temperature measuring element 30 is detected. By a spatial arrangement of the heating element 40 between the measuring electrodes 14 . 16 and the temperature measuring element 30 , Especially in a symmetrical or equidistant arrangement of the heating element 40 with respect to the measuring electrodes 14 . 16 and the temperature measuring element 30 , by a temperature determination with the temperature measuring element 30 Effectively a conclusion on the temperature of the measuring electrodes 14 . 16 to be pulled. This enables effective consideration of the current temperature of the sensor element in the determination of the electrical resistance across the measuring electrodes 14 . 16 ,

In 2 is a sensor element according to a illustrated second embodiment. In this case, the same reference numerals designate the same component components as in FIG 1 ,

The sensor element shown in a plan view according to a second embodiment represents a further possibility, such as an arrangement of the heating element 40 between the measuring electrodes 14 . 16 on the one hand and the temperature measuring element 30 on the other hand can be realized. Here are on the electrically insulating layer 12a both the electrodes 14 . 16 as well as the heating element 40 and the temperature measuring element 30 applied. The heating element 40 is spatially in the same layer plane of the sensor element between the resistor track of the temperature measuring element 30 and the measuring electrodes 14 . 16 arranged. This is preferably done so that at least the heating area of the heating element 40 essentially the same distance to the measuring electrodes 14 . 16 has as the temperature measuring element 30 , In this way, a symmetrical or equidistant arrangement of the heating element 40 with respect to the measuring electrodes 14 . 16 and the temperature measuring element 30 reached; Furthermore, the layer structure can be reduced to a few ceramic layers. Preferably, however, the resistance traces of heating and temperature measuring element 30 . 40 with the further ceramic layer 12f covered against corrosive influences of the gas mixture to be determined.

The present invention is not applicable to those in 1 and 2 illustrated embodiments of a sensor element limited, but it can be made numerous modifications of this sensor element. Thus, it is possible, for example, to provide additional ceramic layers in the sensor element or to simplify the multi-layer structure of the sensor element according to the application, as well as to provide further measuring electrodes. The use of several heating and temperature measuring elements is possible.

The Application of the described sensor element is not on the determination of soot particles in exhaust gases of internal combustion engines, but it can be general for determining the concentration of particles containing the electric conductivity a ceramic substrate when stored change, for example, in chemical Manufacturing processes or exhaust aftertreatment systems used become.

Claims (10)

Sensor element for gas sensors for determining the concentration of particles in gas mixtures, in particular soot sensors, with at least one measuring arrangement exposed to the gas to be determined, at least one heating element integrated into the sensor element ( 40 ) and at least one integrated into the sensor element temperature measuring element ( 30 ), characterized in that the heating element ( 40 ) within the sensor element spatially between the measuring arrangement and the temperature measuring element ( 30 ) is arranged. Sensor element for gas sensors for determining the concentration of particles in gas mixtures, in particular soot sensors, with at least one measuring arrangement exposed to the gas to be determined, at least one heating element integrated in the sensor element (US Pat. 40 ) and at least one integrated into the sensor element temperature measuring element ( 30 ), characterized in that the measuring arrangement and the temperature measuring element ( 30 ) substantially equidistant from the heating element ( 40 ) and / or are arranged to large areas of the sensor element. Sensor element according to claim 1 or 2, characterized in that the measuring arrangement comprises a first and a second measuring electrode ( 14 . 16 ), with which an electrical resistance can be determined. Sensor element according to one of claims 1 to 3, characterized in that the first and the second measuring electrode ( 14 . 16 ) is designed as an interdigital electrode. Sensor element according to one of claims 1 to 4, characterized in that the first and the second measuring electrode ( 14 . 16 ) on an electrically insulating substrate ( 12a ), wherein the electrically insulating substrate contains alumina and / or alkaline earth oxides. Sensor element according to one of the preceding claims, characterized in that an evaluation device is provided, which is a change of between the measuring electrodes ( 14 . 16 ) determines adjacent current flow and / or resistance and outputs this as a measure of the particle concentration. Sensor element according to one of the preceding claims, characterized in that the first and the second measuring electrode ( 14 . 16 ) is arranged in the same layer plane as the heating element ( 40 ) and / or the temperature measuring element ( 30 ). Method for determining the concentration of particles in gas mixtures, in particular of soot in exhaust gases of internal combustion engines, by means of a sensor element according to one of the preceding claims, wherein at least two measuring electrodes ( 14 . 16 ) a voltage is applied and located between the measuring electrodes ( 14 . 16 ) adjusting current flow is determined and output as a measure of the particle concentration. A method according to claim 10, characterized in that a regeneration of the sensor element is initiated, as soon as the between the measuring electrodes ( 14 . 16 ) adjusting current flow exceeds a predetermined value and / or assumes a constant value for a predetermined period. Use of a sensor element according to one of claims 1 to 7 or a method according to any one of claims 8 or 9 for monitoring the operation of a diesel engine or the functionality and / or the loading state of a particulate filter.