DE7522599U - ELECTROCHEMICAL SENSOR FOR DETERMINING THE OXYGEN CONTENT IN EXHAUST GASES - Google Patents

Description

R. $ 27 7

June 24th, 1975 Zr / Ml

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ROBERT B03CH GMBH, 7000 Stuttgart

Electrochemical measuring probe for the determination of the oxygen content in exhaust gases

The invention relates to an electrochemical measuring sensor for the determination of the oxygen content in exhaust gases, in particular in exhaust gases from internal combustion engines, by means of an oxygen concentration chain with ion-conducting solid electrolytes,
the one on its outer surface facing the exhaust gases at least partially an electron-conducting surface with a first one
electrical connection part carries directly or indirectly in electrical connection porous layer and is with its inner surface exposed only to the ambient air in direct or indirect electrical connection with a second electrical connection part and is partially enclosed by a housing, which mostly serves as one of the electrical connection parts .

Electrochemical sensors of this type are known in many variants, but their structure is particularly important for reasons of consistency.

timing and sealing because of the different expansion coefficients the components of the sensor are very expensive; because of these different expansion coefficients of the components of these sensors, the contacting and sealing material within the sensor and the sensor components must always be used are under a relatively high specific pressure.

The invention is based on the object of creating an electrochemical measuring sensor. That comparatively is cheap and its components are under a lower specific pressure for the purpose of electrical contacting and sealing than the components of known electrochemical sensors.

This object is achieved according to the invention in that the contacting and sealing material within the sensor consists of a high-temperature-resistant graphite with a particularly high fire effect and a density of at least 0.5 g / cm ⁵ ; this graphite can be in powder form and arranged like a stuffing box in the sensor, or it can also be used as a molded part.

If the graphite, which has a particularly large spring effect, is arranged within the sensor in a layer that is not too thin, then it is sufficient if the components of the sensor are assembled under pressure on the graphite, while thin Layer thicknesses of the graphite the contacting and sealing material by means of a heat-resistant spring, preferably a disc spring, is to be kept under pretension.

Exemplary embodiments of the invention are shown in the drawing and are described and explained in more detail below; show it

1 shows a longitudinal section through an electrochemical measuring sensor drawn in an enlarged representation according to the invention, wherein the solid electrolyte is designed as a tube closed on one side

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and powdery graphite with a great spring effect as a contacting and sealing material] is used,

FIG. 2 is a longitudinal section through an electrochemical sensor similar to that of FIG. 1, but with Molded parts made of graphite with a particularly large spring effect as a contacting and sealing material is used and

3 shows a longitudinal section through an enlarged Electrochemical sensor shown in the illustration, the solid electrolyte being formed by a disk ^ - ' and molded parts made of graphite with a particularly large spring effect as a contacting and sealing material is used.

The electrochemical measuring sensor 10 shown in FIG. 1 contains an ion-conducting solid electrolyte 11, which is made of stabilized There is cubic zirconium dioxide, is tubular and at its end protruding into an exhaust pipe, not shown, from a floor 12 is closed. This tubular solid electrolyte 11 has on its outside a shoulder 13 and is made of an electron-conducting porous layer 14 on its outer surface Platinum-coated covering the area around which the exhaust gases flow, the shoulder 13 and a contact area 15 of the solid electrolyte 11 covered; between the electron conductive layer 14 and the Solid electrolyte 11 is in the area of the shoulder 13 and the contact area 15 a non-illustrated, electrically insulating glaze is arranged, which reduces the voltage signal of the sensor 10 suppressed. Also, a porous magnesium spinel layer is not shown in the figure, which is on the exhaust gases exposed, electron-conducting layer 14 is applied and as protection against mechanical and thermal attacks of the Exhaust gas is used.

The tubular solid electrolyte 11 is on its surface facing the interior 16 with an electron-conducting path

provided that bi3 and extends into the region of the base 12 is also made of platinum \ this conductor track 17 of the interior space 16 extends up to the connection side in a widening 18th

The connection-side section of the plague electrolyte 11 is head-shaped and is encompassed by a housing 19, which has electrical conductivity and can consist of heat-resistant steel; this housing 19 is drilled out in steps in such a way that the connection-side bore section 20 has the largest diameter and the central bore section 21 has a larger diameter than the exhaust-side bore section 22. The shoulder formed between the bore sections 21 and 22 is denoted by 23 and carries de. i Plansch 24 of a protective tube 25 _} which surrounds the part of the solid electrolyte 11 exposed to the exhaust gas and is provided with openings 26 for the access of the exhaust gas. On its outside, the housing 19 has a hexagon wrench 27 and a screw-in thread 28 for tight and secure installation in the exhaust pipe, not shown.

Between the middle bore section 21 and the contact area 15 of the solid electrolyte 11, an annular space 29 is formed which is filled with a contacting and sealing material 30 is what, according to the invention, consists of a high temperature resistant Graphite is made with a particularly large spring effect and has a density of at least 0.5 g / cm · ^; this graphite is for example under the trade name "Sigraflex" from Sigri Elektr ~ - graphit GmbH available.

The interior 16 of the solid electrolyte 11 starts at its connection side Widening 18 on the exhaust side into a bore 31 with a smaller diameter; while the housing 19 is the first electrical Connecting part of the sensor 10 is used, protrudes into the connection-side end portion of the bore 31, a pipe 32 as a second electrical Connection part of the probe 10 into it. This metallic tube 32 has the plague electrolyte in the area of the widening 18 an outwardly facing bead 33, has in the direction of the

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connection-side end portion comprises a ventilation opening 34 and with its connection-side end section, a connection cable 35; by pinching 36, the connecting cable 35 is in the Pipe 32 set and an insulating hose 37, which partially the end portion of the tube 32 and part of the connecting cable 35, serves as a kink protection for the connection cable 35 - A tubular ceramic nozzle 38 is pushed onto the tube 32, which rests on the one hand on the bead 33, protrudes from the housing 19 on the connection side and has a shoulder on its outside Owns 39; the end section of the ceramic connector 38 facing the bead 33 dips into the widening 18 of the plague electrolyte 11 and forms together with a part of the tube 32 and the wall of the widening l8 a second annular space 40, which is with the same Contacting and sealing material 30 is filled like that Annulus 29; the annular spaces 29 and 40 are approximately the same Cross-section of the sensor 10 and have: approximately the same load cross-sections, whereby optimal suspension properties through the Contacting and sealing material 30 can be achieved.

The sensor 10 is held together by a metal washer 4l, which rests on the shoulder 39 of the ceramic connector 38 and from a beaded edge 42 of the housing 19 while exercising Pressure is held; the contacting and sealing materials 30 in the annular spaces 29 and 40 are under pretension held. Instead of the metal ring washer 4l can with extraordinary Loading of the sensor 10, a heat-resistant spring, preferably a plate spring, can be used as an aid, which is below Bias is held.

The contacting and sealing material 30 is powdery in the present example and is like a stuffing box within the sensor 10 arranged. '

In Fig. 2, an electrochemical sensor 10 'is shown, its solid electrolyte 11 ', housing 19', protective tube 25 'and metal ring washer or plate spring 4l 'largely the corresponding

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Components of the sensor 10 in Pig. 1 corresponds. The essential feature of this sensor 10 * is the use of a contacting ^ and sealing material 30 ·, which also consists of high-temperature-resistant graphite with a particularly large spring effect and a density of at least 0.5 g / cm ^-3 , but is not powdery as in the case of the sensor 10 according to FIG. 1 but is designed as a molded part. The contact area 15 'of the solid electrolyte II ¹ rests on an annular shaped part 51 made of the contacting and sealing material 30', which in turn over the flange 24 'of the protective tube 25' and another. Molded part 52 made of the contacting and sealing material 30 'is connected to the housing 19' in an electrically conductive and sealing manner.

In this embodiment, the conductor track 17 'of the solid electrolyte 11' leads the measuring sensor 10 'to the connection-side end face 53 of the solid electrolyte 11' and is here also in contact ^{with an annular shaped part 54 made of the contacting and sealing material 30 1;} an electrically conductive cup washer 55 with a central bore 56 engages with its edge 57 over the molded part 54 and a small section of the solid electrolyte 11 '. A ceramic connector 38 ', which also has a shoulder 39' on its outside, presses with its end face 58 on the plate washer 55 is welded to the plate washer 55 and is rolled with its connection-side end portion to ein.Hülse 6l and holds the connecting cable 35 therein. The entry of the ambient air into the interior 16 * of the solid electrolyte 11 'takes place through the longitudinal slot (not shown) in the sleeve 6l. the ceramic socket longitudinal bore 59 and the central bore 56 in the plate washer 55

In Fig. 3, a sensor 10 "is shown, the solid electrolyte 11 "is an inexpensive disk. This solid electrolyte disk 11" consists of the same material as the Solid electrolytes in the sensors 10 and 10 'according to the figures

1 and 2 and also has an electron-conducting layer 14 ″ and above it also a porous magnesium spinel layer (not shown) and also has an electron-conducting contact layer 17 "on the opposite side. This plague electrolyte disk 11" is Fixed in front in a metal sleeve 70, the one pulled inward Has stop 71. Between the plague electrolyte disk 11 ″ and the stop 71 ″ of the metal sleeve 70 is a circular ring-shaped Molded part 72 made of the contacting and sealing material also used in the sensors 10 and 10 'according to FIGS. 1 and 2 30 "made of high-temperature-resistant graphite with a particularly large peder effect and also on the opposite side The solid electrolyte disk 11 ″ is such a molded part 73. The flange 7 ^ is located on this molded part 73 a tube 75, which at its other end portion as well is designed as in the case of the sensor 10 according to FIG. 1; the molded part 73 and the pipe flange 7 ^ are in a recess 76 of a ceramic pipe socket 38 ". While · the metal sleeve 70 is fixed by means of a caulking rim: 77 in the housing Ϊ9", corresponds to the further Aui'bar- the measuring sensor 10 ″ essentially that of the Sensor 10 in Fig. 1. - Especially this embodiment of the Sensor 10 "is extremely inexpensive and also robust in construction.

Claims (3)

Expectations 1. Electrochemical measuring probe for the determination of the oxygen content in exhaust gases, in particular in exhaust gases from internal combustion engines, by means of an oxygen concentration chain with ion-conducting Plague electrolyte, which on its outer surface facing the exhaust gases at least partially has an electron-conducting, with a first electrical connection part directly or indirectly in electrical. Connecting porous layer carries and with its inner surface, which is only exposed to the ambient air, in direct or indirect electrical connection stands with a second electrical connection part and is partially surrounded by a housing, which is mostly as one of the electrical connection parts are used, characterized in that the contacting and sealing material (30, 30 ', 3O ") within of the measuring sensor (10, 10 ', 10 ") consists of a high-temperature-resistant graphite with a particularly large spring effect and has a density of at least 0.5 g / cnr. 2. Sensor according to claim 1, characterized in that the contacting and sealing material (30) is powdery and is arranged like a stuffing box in the sensor (10). 3. Sensor according to claim 1, characterized in that the contacting and sealing material (30 ', 30 ") is a molded part (51, 52, 5 ¹ »; 72, 73). H. Measuring sensor according to one of Claims 1 to 3, characterized in that the contacting and sealing material (30, 30 ', 30 ") is held under pretension by means of a heat-resistant spring (111), preferably a cup spring. 7522599 13.B1.77