DE102008002734A1 - lambda probe - Google Patents

Abstract

A lambda probe (10) is proposed for measuring the exhaust gas lambda in an exhaust gas region of an internal combustion engine, which contains a first electrode (20) which is arranged in a measuring gas cavity (18) connected to the exhaust gas, which contains a second electrode (24) which is connected via an oxygen ion-conducting solid electrolyte (22) to the first electrode (20) and which is arranged in a reference gas channel (26). The lambda probe (10) according to the invention is characterized in that a specifically formed oxygen reservoir (40, 50, 62, 64, 70) is provided in the reference gas channel (28).

Description

The The invention is based on a lambda probe according to the type of independent Claim, in particular for detecting the Abgaslambda in a Exhaust duct of an internal combustion engine is suitable.

With Lambda air ratio in combustion technology is the ratio between an actually offered air mass and a for combustion theoretically required air mass, the stoichiometric air mass, called. Corresponding have fatty gas mixtures, ie gas mixtures with a Fuel surplus, an air ratio lambda <1, while lean gas mixtures, ie gas mixtures with an excess of air, an air ratio lambda> 1 exhibit.

State of the art

In the DE 199 41 051 A1 a broadband lambda probe is described, which has a measuring gas cavity, which is connected via a diffusion barrier with the exhaust gas to be examined. In the sample gas cavity, an inner pumping electrode is arranged, which forms a pump cell with an outer, the exhaust gas exposed pump electrode and a lying between the pump electrodes oxygen ion conductive solid electrolyte. With the pumping cell, oxygen ions can be pumped in through the solid electrolyte from the sample gas cavity or into the sample gas cavity. In addition to the pumping cell, there is a measuring cell which is located between the inner pumping electrode and a reference gas electrode. The inner pumping electrode and the reference gas electrode are also separated from each other by an oxygen ion-conducting solid electrolyte. The reference gas electrode is arranged in a reference gas channel.

The Measuring cell corresponds to a Nernst cell, in which the thermodynamic Balance between the inner pumping electrode and the reference electrode forming potential difference the logarithm of the ratio the partial pressure of the gas to be examined in the sample gas cavity and the partial pressure of the air in the reference gas channel proportional is. The aim of a measurement of the exhaust gas lambda is to determine the oxygen partial pressure in the To influence the sample gas cavity such that the Nernst potential constant at a certain value (for example 450 mV), which approximates lambda = 1. A circuit arrangement provides for this purpose a pumping voltage with which the outer Pumping electrode is applied. The pump voltage leads to a pumping current. The polarity and the magnitude of the pumping current depend on whether and by what amount the particular Nernst voltage is exceeded or fallen below. Which adjusting pumping current is a measure of the exhaust lambda.

In the DE 10 2006 061 954 A1 (Not prepublished) is given in comparison to the previously described lambda probe simpler lambda probe in which the outer pump electrode is omitted. The simple low-cost lambda probe is suitable, in particular, for lambda measurement of the lambda in an exhaust gas duct of a lean-burn internal combustion engine. The lambda probe contains a first electrode and a second electrode, which are connected to one another via an oxygen ion-conducting solid electrolyte. The first, arranged in a measuring gas cavity electrode is connected via a diffusion barrier with the exhaust gas to be examined. The second electrode is arranged in a reference gas channel. The reference gas channel may be filled with an oxygen-permeable porous filler. By optionally provided filling of the reference gas channel and its geometric configuration is to be achieved, on the one hand optimal removal of oxygen from the second electrode is ensured and on the other hand, penetration of impurities in the reference gas channel is prevented.

The known lambda probe is realized as a limit current Magersonde, at which a pumping current by applying a sufficiently high potential difference occurs between the two electrodes, the first in the Range lambda> 1 until lambda = 1 is proportional to the air ratio lambda. By admission of the two electrodes with a potential that is between opposite to the two electrodes adjusting Nernst voltage is, with the known lambda probe in the rich lambda range be measured. Since the Nernst voltage is low in the lean range (about 200 mV) and in the rich area to a higher value (about 900 mV) jumps, can be applied to the electrodes pumping voltage have the same polarity both in the lean and in the rich region, the potential in the lean area to a higher Value to be set in the rich range. Considering the Nernst voltage occurring in different operating states indicates the occurring between the boundary layers behind the electrodes effective pumping voltage for the negative oxygen ions during the transition from fat to lean or vice versa, a sign change, so that the negative oxygen ions in lean exhaust gas from the first to the second electrode and with rich exhaust gas from the second to the first Electrode be transported.

The invention has for its object to provide a lambda probe for detecting the exhaust lambda is suitable in an exhaust passage of an internal combustion engine, wherein the internal combustion engine on the one hand lean and on the other hand at least temporarily operated fat.

The Task is indicated by the independent claim Characteristics solved.

Disclosure of the invention

The Lambda probe according to the invention for measuring the Abgaslambda in an exhaust region of an internal combustion engine is derived from a sensor element consisting of a first arranged in a sample gas chamber electrode and contains a second electrode arranged in a reference gas channel, the via an oxygen ion-conducting solid electrolyte are connected. According to the invention is in the reference gas channel a targeted formed oxygen storage provided.

The Targeted formation of the oxygen storage means that action are taken, which at least temporarily the storage of oxygen in the reference gas channel or at least the provision of oxygen at the second electrode.

Of the Oxygen storage represents at least for a given Measurement time oxygen available during the measurement in the rich exhaust gas at lambda <1 from the reference gas channel into the sample gas chamber the solid electrolyte can be pumped back. Thereby can at least for the specific measuring time at a fat Exhaust gas to be measured. The measuring time depends on the available oxygen at the second electrode.

The lambda probe according to the invention is particularly suitable for lambda measurement in the exhaust gas region of an internal combustion engine, which is operated mainly lean, but which is temporarily operated in bold or at least stoichiometric. Such an operation of the internal combustion engine is provided, in particular, if exhaust gas purification devices, such as, for example, a NO _x storage catalytic converter or a particle filter, are arranged in the exhaust gas channel. In the fat phases, unburned hydrocarbons are introduced into the exhaust gas area. The unburned hydrocarbons may exothermically react in the exhaust region with, for example, residual oxygen present in the exhaust gas to heat exhaust purification systems such as NO _x storage catalysts, particulate filters and the like, or may be used to regenerate exhaust gas purification systems such as NO _x storage catalysts.

The Lambda probe according to the invention allows Thus, the lambda control not only in the lean area, but at least for the given measuring time also in the fat or at least stoichiometric lambda range.

advantageous Further developments and refinements of the invention Approach arise from dependent claims.

A Embodiment provides that the oxygen storage at the second Electrode adjoins. When the oxygen storage is adjacent to the second electrode is provided, if necessary, in the specification of a bold Lambda's stored oxygen immediately for the pumping process to disposal.

A Another embodiment provides that the reference gas channel a Contains oxygen storage cavity and that at the output side End of the reference gas channel provided a flow resistance is. In the oxygen storage cavity can during the lean Operation of the internal combustion engine an oxygen over pressure built up become. A loss of oxygen is due to the flow resistance throttled.

A particularly simple realization of this embodiment provides that the oxygen storage cavity a larger Cross section of the reference gas channel and that the flow resistance is realized accordingly by a smaller cross-section.

A Further development of this embodiment provides that the flow resistance at least partially realized with an exhaust diffusion barrier. In addition to the throttling of the oxygen flow prevents the exhaust air diffusion barrier the ingress of contaminants into the reference gas channel.

additionally to the exhaust diffusion barrier, an oxygen storage diffusion barrier be provided, for example, a high porosity for storing oxygen. The oxygen storage This is at least partially due to the oxygen storage diffusion barrier realized.

A Continuing this measure provides that in addition an oxygen storage cavity is provided at the second Electrode adjoins. As a result, if necessary, is particularly fast Oxygen available.

A Another development of this measure provides that the intended for the oxygen storage diffusion barrier Volume is greater than that for the exhaust diffusion barrier. This measure can do this for the oxygen storage provided volumes are varied.

An embodiment provides that the oxygen storage contains a material that stores oxygen by adsorption or absorption. Such a material is for example a non-stoichiometric oxide such as doped CeO _2-x, or La _1-x Sr _x Fe _y Co _1-y O _3-d. Such a non-stoichiometric oxide stores oxygen via a chemical reaction.

For example may be the exhaust diffusion barrier, but preferably the oxygen storage diffusion barrier at least in sections contain the oxygen-storing material.

A Embodiment provides that the oxygen-storing material at least on a part of the surface of the reference gas channel is applied. An additional or alternative measure sees that the material is applied to the second electrode or that the second electrode contains the material.

embodiments The invention are illustrated in the drawing and in the following description explained in more detail.

Brief description of the figures

1 shows a known from the prior art lambda probe in an operating condition at an air ratio lambda> 1,

2 shows a known from the prior art lambda probe in an operating condition at an air ratio lambda <1,

3 shows a lambda probe according to the invention with an oxygen storage cavity and a flow resistance,

4 shows a lambda probe according to the invention with a channel formed oxygen storage cavity,

5 shows a lambda probe according to the invention with an exhaust diffusion barrier and an additional oxygen storage diffusion barrier,

6 shows the in 5 shown lambda probe with an additional oxygen storage cavity in the region of the second electrode,

7 shows an oxygen storage cavity formed as a channel, which is arranged in a further plane of the lambda probe according to the invention,

8th shows a lambda probe according to the invention, in which the oxygen storage is at least partially realized as oxygen-storing material and

9 shows a lambda probe according to the invention according to 8th in which the oxygen-storing material is associated with the second electrode.

Detailed description the embodiments

1 shows a lambda probe 10 that is an exhaust flow 12 a not shown in detail internal combustion engine is exposed. Part of the exhaust gas passes through a supply air duct 14 and via an exhaust diffusion barrier 16 into a sample gas chamber 18 in which a first electrode 20 is arranged. The first electrode 20 is via an oxygen ion conducting solid electrolyte 22 with a second electrode 24 connected in a reference gas channel 26 is arranged, which at its output end 28 For example, in the ambient air or in an exhaust duct not shown in detail of the engine opens. The sample gas chamber 18 and the reference gas channel 26 and thus the two electrodes 20 . 24 are via a gas-tight separation layer 32 separated from each other. For heating the lambda probe 10 is a heating element 34 intended.

1 shows the operation of the lambda probe 10 especially with a lean exhaust stream 12 , The two electrodes 20 . 24 are connected to a pump voltage source not shown in detail, which provides a lean operation pumping voltage UP, m, wherein the positive potential at the second electrode 24 lies. The pump voltage source is set to 800 mV, for example. In lean operation occurs between the two electrodes 20 . 24 a lean operating Nernst voltage UN, m, which is comparatively low and, for example, at 200 mV, wherein the positive potential at the second electrode 24 occurs. The lean operation pumping voltage UP, m and the lean operation Nernst voltage UN, m overlap, so that between the two electrodes 20 . 24 for the transport of oxygen ions an effective lean-operation pumping voltage UPeff, m is available, which corresponds to the difference between the lean-operation pumping voltage UP, m and the Ma gerbetrieb Nernstspannung UN, m, ie about 600 mV, wherein the positive potential at the second electrode 24 occurs. Thereby, a lean oxygen ion transport O ^{2 -m} from the first to the second electrode takes place 20 . 24 instead, so oxygen from the sample gas space 18 to the reference gas channel 26 pumped into the ambient air or into the exhaust duct. The lean operation pumping current IP, m is a limiting current that is proportional to the air ratio lambda, based on the stoichiometric value.

2 shows the in 1 represented Lamb dasonde 10 in an operating condition with a rich exhaust gas flow 12 ,

Those in 2 parts shown with the in 1 The same reference numerals correspond to each other. This agreement also applies to the following figures.

In an exhaust gas flow 12 with oxygen deficiency based on a stoichiometric ratio occurs between the electrodes 20 . 24 a considerably higher fat operation Nernst voltage UN, f, which is for example at 900 mV, whereby the positive potential continues at the second electrode 24 occurs. In rich operation, the lambda probe should 10 Oxygen from the reference gas channel 26 to the sample gas chamber 18 pump. In order for such rich operation oxygen flow O ^2- f to occur, the effective rich operation pump voltage UPeff, f must be poled such that the positive potential at the first electrode 20 occurs. In order to reach these potential conditions, it must be connected to the electrodes 20 . 24 applied pump voltage to a rich operation pumping voltage UPeff, f set. In this case, a potential reversal with regard to the fact that the rich operation Nernst voltage UN, f is at a comparatively high potential of, for example, 900 mV, is not absolutely necessary. A sign reversal of the effective rich operation pumping voltage UPeff, f is already achieved when the potential of the rich operation pumping voltage UP, f is reduced to the lean operation to, for example, 300 mV, wherein the positive potential continues at the second electrode 24 is applied. For the effective rich pumping voltage UPeff, f then also 600 mV are available, with the positive potential at the first electrode 20 occurs. The rich operation pumping current IP, f is also a limiting current which is proportional to the air ratio lambda, based on the stoichiometric value. The lean operation pumping current IP, m flows in the opposite direction compared to the lean operation pumping current IP, m. When the air ratio lambda = 1 occurs when changing the pump voltage UP, a sign reversal of the pump current IP.

In rich operation, only a limited amount of oxygen in the region of the second electrode is available in the lambda probe according to the aforementioned prior art, since the reference gas channel is optimized for removing oxygen as quickly as possible. The lambda probe according to the invention 10 provides a targeted formed oxygen storage, which makes it possible to create a supply of oxygen. This oxygen is in case of need, ie in the rich operation of the lambda probe according to the invention 10 sufficiently available for a given period of operation.

The specifically formed oxygen storage can be realized in different ways. A first embodiment is in 3 shown in which the reference gas channel 26 an oxygen storage cavity 40 contains, to the output end 28 through a flow resistance 42 is limited. The flow resistance 42 can according to a development to the output end 28 of the reference gas channel 26 extend. The oxygen storage cavity 40 may according to an embodiment by a larger cross-section of the reference gas channel 26 compared to the cross section of the flow resistance 42 be realized, which has a smaller cross-section. The volume of the oxygen storage cavity 40 will be adapted to the requirements. The flow resistance 42 can with an exhaust diffusion barrier 44 be at least partially filled, which the effect of the flow resistance 42 further increased or what the ingress of dirt into the oxygen storage cavity 40 prevented from the ambient air or the exhaust passage.

Another embodiment is in 4 shown in which the reference gas channel 26 is maintained largely unchanged compared with the known from the prior art reference gas channel, but with an oxygen storage cavity 50 is provided, which is realized by a unilaterally ge closed oxygen storage channel, the opening 52 in the region of the second electrode 24 is provided.

Another embodiment is in 5 shown in which the reference gas channel 26 at least partially with an exhaust diffusion barrier 60 is filled and in addition to the oxygen storage cavity 40 . 50 provided with an oxygen storage diffusion barrier 62 is filled. A development of this embodiment is in 6 shown, in addition, another oxygen storage cavity 64 is provided, which at the second electrode 24 borders. According to one embodiment, it may be provided that that for the oxygen storage diffusion barrier 62 provided volume is greater than the volume for the exhaust diffusion barrier 60 ,

At the in 7 the embodiment shown is the oxygen storage cavity 40 . 50 according to the in 4 embodiment shown realized as an oxygen storage channel, but in another plane of the lambda probe 10 is arranged. At the in 7 the embodiment shown is the opening 52 the oxygen storage channel according to an embodiment up to the second electrode 24 introduced.

At the in 8th shown Ausführungsbei Game is the oxygen storage with a material 70 realized that stores oxygen by adsorption or absorption. In the material 70 it is, for example, a non-stoichiometric oxide such as CeO _2-x or La _1-x Sr _x Fe _y Co _1-y O _3-d . At the in 8th embodiment shown is the material 70 in the oxygen storage cavity 40 . 50 optionally, the oxygen storage diffusion barrier 62 may additionally contain and optionally the oxygen storage cavity 64 in particular adjacent to the second electrode 24 can have.

An alternative, in 9 shown embodiment of the lambda probe according to the invention 10 Provides that material 70 , which can store oxygen by adsorption or absorption, the second electrode 24 assigned. At the in 9 embodiment shown is the material 70 on the second electrode 24 applied. If as material 70 a highly electron-conductive non-stoichiometric oxide such as La _1-x Sr _x Fe _y Co _{1 -y} O _{3-d is} used, the second electrode 24 also complete with the material 70 be realized or in mixture with ZrO _2. Furthermore, it is possible to use the material 70 at least partially coating the surface of the reference gas channel 26 consulted.

In the lean phase of the lambda probe 10 becomes due to the pumping voltage UP, m oxygen from the sample gas space 18 into the oxygen storage 40 . 50 . 62 . 64 . 70 of the reference gas channel 26 pumped. In the case of an exhaust lambda of, for example, 1.7, corresponding to 8.29% O 2 in N 2, and a lean operation pumping current of a maximum of a few 100 microamps, an oxygen overpressure in the steady state lean operation of, for example, 2 bar to 30 bar in the oxygen storage 40 . 50 . 62 . 64 . 70 be achieved. Preferably, the overpressure between 2 bar and 10 bar is set. During operation of the lambda probe according to the invention 10 The stored oxygen can be stored by the rich operation pumping voltage UP, f and the corresponding rich operation pumping current IP, f from the oxygen storage 40 . 50 . 62 . 64 . 70 back to the sample gas chamber 18 be pumped, there for the oxidation of oxidizable exhaust gas components in the sample gas cavity 18 is available, wherein the rich operation pumping current IP, f also in the case of the rich operation of the lambda probe according to the invention 10 reflects a measure of the exhaust lambda.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• - DE 19941051 A1 [0003]
• DE 102006061954 A1 [0005]

Claims (14)

Lambda probe for measuring the exhaust gas lambda in an exhaust gas region of an internal combustion engine, which has a first electrode ( 20 ), which in a sample gas cavity connected to the exhaust gas ( 18 ), which has a second electrode ( 24 ), which via an oxygen ion conducting solid electrolyte ( 22 ) with the first electrode ( 20 ) and in a reference gas channel ( 26 ), characterized in that in the reference gas channel ( 28 ) a specifically formed oxygen storage ( 40 . 50 . 62 . 64 . 70 ) is provided. Lambda probe according to claim 1, characterized in that the oxygen storage ( 40 . 50 . 62 . 64 . 70 ) on the second electrode ( 24 ) adjoins. Lambda probe according to claim 1, characterized in that the reference gas channel ( 26 ) an oxygen storage cavity ( 40 . 50 . 64 ) and that at least at the output end ( 28 ) of the reference gas channel ( 26 ) a flow resistance ( 42 ) is provided. Oxygen sensor according to claim 3, characterized in that the oxygen storage cavity ( 40 . 50 . 64 ) by a larger cross-section of the reference gas channel ( 26 ) and the flow resistance ( 42 ) by a smaller cross-section of the reference gas channel ( 26 ) are realized. Lambda probe according to claim 1, characterized in that the reference gas channel ( 26 ) an oxygen storage cavity ( 40 . 50 . 64 ), which is realized by a closed oxygen storage channel whose opening ( 52 ) in the region of the second electrode ( 24 ) is provided. Lambda probe according to claim 3, characterized in that the flow resistance ( 42 ) at least partially an exhaust diffusion barrier ( 44 ) contains. Lambda probe according to claim 6, characterized in that the oxygen storage ( 40 . 50 . 62 . 64 . 70 ) at least partially as a storage diffusion barrier ( 62 ) is realized. Lambda probe according to claim 7, characterized in that in addition an oxygen storage cavity ( 64 ) provided on the second electrode ( 24 ) adjoins. Lambda probe according to claim 6 and 7, characterized in that the oxygen storage diffusion barrier ( 62 ) provided volume is greater than that for the exhaust diffusion barrier. Lambda probe according to claim 1, characterized in that the oxygen storage ( 40 . 50 . 62 . 64 . 70 ) a material ( 70 ) which stores oxygen by adsorption or absorption. Lambda probe according to claim 10, characterized in that the material ( 70 ) contains a non-stoichiometric oxide. Lambda probe according to claim 10 and 6 or 10 and 7, characterized in that the exhaust diffusion barrier ( 44 . 60 ) or the storage diffusion barrier ( 62 ) at least in sections the material ( 70 ) contain. Lambda probe according to claim 10, characterized in that the material ( 70 ) at least on a part of the surface of the reference gas channel ( 26 ) is applied. Lambda probe according to claim 10, characterized in that the material ( 70 ) on the second electrode ( 24 ) or that the second electrode ( 24 ) the material ( 70 ) contains.