DE19937160A1 - Gas sensor for exhaust gases from IC engine has sensor element fixed in bore of housing and enclosed by polarized graphite-containing sealed body placed on at least one part its length - Google Patents

Abstract

A gas sensor has a sensor element (1) fixed in a bore of a housing (5) and enclosed by a polarized graphite-containing sealed body (7) placed on at least one part its length. An Independent claim is also included for the production of the gas sensor comprising arranging a sensor element (1) in a bore of a housing (5), surrounding with a polarized graphite-containing sealed body (7) and exerting a pressure on the sealed body. Preferred Features: The sealed body is tensioned in the longitudinal direction of the sensor element between two supporting bodies (3,4). A layer of ceramic powder (9,10) is inserted between each supporting body and the sealed body.

Description

State of the art

The invention relates to a gas sensor, in particular re for exhaust gases from an internal combustion engine, with a fixed in a bore of a housing by egg graphite-containing sealing body on at least one egg long part of its length is tightly enclosed stretched sensor element. Such a gas sensor is known from DE 44 36 580 A1. It also affects a method of making such a sen sors.

One under all conceivable operating conditions Internal combustion engine effective sealing of the sensor lements is for the proper functioning of such a gas sensor of great importance. If exhaust gases or vaporized fuel Penetrate seal, so they can in the refe penetration gas space of the sensor and thereby falsify measurement results. Exist at the same time high demands on temperature resistance such a seal because the gas sensor is in operation the exhaust gas of the internal combustion engine, which is hot up to 1000 ° C machine is exposed and in the area of the seal  set temperatures of a maximum of 600 to 700 ° C can be enough.

There are therefore a multitude of different you systems have been tested. A practical one applied solution consists in the use of zwi fixed support bodies enclosed you packs of steatite powder or steatite Boron nitride sandwich packs.

Pure steatite packs have problems with the tightness against liquid and vapor Petrol. So it can be especially repeated False starts of a cold internal combustion engine on penetrate of gasoline vapors into the reference gas space of the sensor. With steatite boron nitride Sandwich packs can with unfavorable tolerance fit between the sensor element and the packing similar problems occur.

There is therefore great interest in alternatives Sealing materials for gas sensors of the above a kind.

So far, graphite-sealed exhaust gas sensors are not have been mass-produced because they too have problems with regard to the tightness under all applications conditions.

Advantages of the invention

The present invention turns a gas sensor of the type mentioned, created under excellent density properties in all operating conditions  promises. This will be an essential one This improves the sealing properties is enough that a graphite of the sealing body is a pola rised graphite is selected, that is a Gra phit, the slats of which are superficially thin Layers of polar compounds are coated. Such a polarized graphite becomes an accessory game from Molykote as a solid lubricant or part of lubricant together marketed. Such a polarized one Graphite not only has improved wetting properties on the surface oxidized and the semi-polar surfaces of ferrous materials, son also on ceramic materials from which Gas sensors of the type mentioned at the beginning element and possibly the one for clamping the Seal body used support body manufactured are. At the same time it can be assumed that the Wettability of such a polar graphite for Gasoline and thus its permeability to gasoline and gasoline vapors over conventional graphite is reduced.

Inside the gas sensor is the graphite one Sealing body preferably in the longitudinal direction of the Sen sorelements clamped between two support bodies, which consist of a sintered ceramic material can. In addition, it is preferred that between each the support body and the sealing body a ceramic Powder is included, which leads to homogeneous ver division of the clamping pressure over the entire surface surface of the sealing body.  

To the electrically conductive sealing body against that It is preferable to insulate the gas sensor housing as the sealing body in the radial direction of the Sen sorelements electrically from a first ring insulating material.

A second, outer ring can also be used the material of the sealing body between the ring insulating material and the inner wall of the bore be included. The diameter of the sealing body pers and the two rings are expediently so chosen that the ring made of electrically insulating Material in an annular gap between the second Ring and the sealing body when assembling the gas sensors introduced, in particular pressed can. The ring should be pressed out electrically insulating material on balance a ra an inward pressure acts on it, that is, the inward pressure of the two The first ring should be larger than that outward pressure of the sealing body to avoid the first ring when pressing in jumps.

The first ring can be made of boron nitride or, for example from a densely sintered ceramic, in particular consist of steatite or aluminum oxide.

To ensure complete electrical insulation of the To ensure sealing body, the expansion tion of the first ring in the longitudinal direction larger than that of the sealing body. The first ring can at its axial ends in grooves the support body or, when using a ceramic powder between  the support body and the sealing body into which intervene ceramic powder.

The invention further relates to a method for Installation of a gas sensor, especially a gas sensors as described above.

Further features and advantages of the invention result from the following description of Ausfüh Example with reference to the figures.

characters

Fig. 1 shows an axial section of the head region of a gas sensor according to a first embodiment of the invention; and

Fig. 2 shows an axial section egg nen sealing body on a Sensorele element and its surroundings according to a second embodiment.

Description of the embodiments

Fig. 1 shows in axial section the head region egg nes gas sensor for determining the oxygen content in the exhaust gas of an internal combustion engine according to a first embodiment of the invention. The gas sensor comprises a sensor element 1 in the form of a elongated plate made of ceramic material, which is shown in the figure seen from a narrow side. The sensor element 1 carries at its lower end in the fi gur a sensitive portion which, shielded from direct flow by a concentric double-walled protective tube 2 , is exposed to the exhaust gas of the internal combustion engine. Electrical connections at the end of the sensor element 1 facing away from the sensitive section (not shown), the NEN for supplying with a heating current and for deriving the measurement signals. The structure of the sensor element 1 is known and is not dealt with here.

Two essentially cylindrical support bodies 3 , 4 made of oxide ceramic each have a continuous slot through which the sensor element 1 extends. The support body 1 , 4 are spaced from each other in a bore of a housing part 5 in the longitudinal direction of the sensor element 1 and are essentially held free of play. The lower support body 4 facing the sensitive section of the sensor element is mounted on a shoulder of the housing part 5 via a sealing ring 6 .

In the space between the two support bodies 3 , 4 , a sealing body 7 made of polarized graphite and a first ring 8 made of boron nitride are enclosed between an upper and a lower layer 9 , 10 made of powdered, annealed ceramic material. The arrangement of support bodies, sealing body, first ring and ceramic material is held together by a protective sleeve 11 under pressure, which is seteils 5 locked to an annular projection at the upper end of the bore of the housing.

When mounting the gas sensor, the sealing body 7 made of graphite is preferably preformed outside of the bore by pressing into a manageable body. This body has a slot through which the sensor element 1 can be carried out with low tolerance. The sensor can then be assembled by first inserting the sensor element 1 with the lower support body 3 into the bore of the housing part 5 , then filling the layer 10 of powdered ceramic material and fitting the sealing body 7 and the first ring 8 . Then the second layer 9 is filled in and the hole is filled by plugging the support body 3 onto the sensor element 1 and closed.

In order to achieve a tight seal between the sealing body 7 and the sensor element 1 , a pressure is exerted on the supporting body 3 in the longitudinal direction of the sensor elements, which layers 9 and 10 are evenly distributed over the end faces of the supporting body or the sealing body by means of the powder 7 distributed and leads to the fact that the sealing body 7 fits tightly to the surface of the sensor element 1 . This pressure can be maintained by the attached protective sleeve 11 when the sensor is fully assembled. The polarity of the graphite used favors an intimate connection between the graphite of the sealing body 7 and the likewise polar surface of the oxide-ceramic sensor element 1 .

The outer diameter of the first ring 8 corresponds essentially to the inner diameter of the bore of the housing part 5 without play. This prevents the ring 8 from being blown up when the sealing body 7 is pressed together.

Through the ring 8 and the powder layers 9 , 10 , the sealing body 7 is electrically insulated from all sides against the metallic housing part 5 , so that leakage currents from the housing part do not reach the sensor element 1 and cannot falsify the measurement results obtained with it.

Fig. 2 shows the sensor element 1 and the housing part 5 with the sealing arrangement taken in the bore of the housing part according to a second embodiment of the invention.

The sealing arrangement in turn comprises two support bodies 3 , 4 and two in the space between the support bodies 3 , 4 and the inner wall of the bore on layers 9 , 10 made of powdered, ge-annealed ceramic material. A sealing body 7 made of polarized graphite is enclosed between the two layers 9 , 10 , a first ring 8 made of densely sintered ceramic, for example made of aluminum oxide or steatite, and the sensor element 1 . The outer diameter water of the first ring 8 is significantly smaller than the inner diameter of the drilling tion of the housing part 5 ; in the annular space between the two a second ring 12 is arranged, which, like the sealing body 7, consists of polarized graphite and has the same thickness in the longitudinal direction of the sensor element 1 .

The parts made of polarized graphite are pre-pressed as in the first embodiment and inserted as finished molded bodies into the bore of the housing part 5 when the gas sensor is being installed. The first ring 8 is then introduced into an annular gap that remains between the two. The diameter of the sealing body 7 and the rings 8 , 12 are selected so that a plastic deformation of the sealing body 7 is required for the insertion of the first ring 8 . By this plastic deformation material of the sealing body 7 is displaced inwards in the direction of the sensor element 1 , so that a tight connection between the sealing body 7 and the sensor element 1 is already achieved when the ring 8 is inserted.

In order to avoid that the first ring 8 bursts when inserting and deforming the sealing body 7 , the second ring 12 is provided. This is dimensioned so that it is also plastically formed during insertion and thus exerts a radially inward pressure on the first ring 8 , through which the outward pressure of the sealing body 7 is at least partially compensated. It is easiest if the dimensions are chosen so that overcompensation occurs, because radially inward pressures of the second ring 12 can bear the first ring 8 to a considerable extent without being destroyed by it.

A similar pressing of the ring B onto the sealing body 7 is of course also possible in the embodiment from FIG. 1; However, it is also important to ensure that the outer diameter of the ring 8 and the inner diameter of the bore of the housing part 5 are virtually free of play, so that the housing part at least partially compensates for the deformation of the sealing body 7 by the ring 8 is able to compensate.

The outer ring 2 can also be made of a different material than the polarized graphite of the sealing body 7 , since in the former it depends essentially only on its plastic deformability and its friction properties in the cold state when the first ring 8 is inserted, but not good wetting ability on polar surfaces.

Claims (15)

1. Gas sensor, in particular for exhaust gases of an internal combustion engine, with a in a bore of a Ge housing ( 5 ) fixed by a graphite-containing sealing body ( 7 ) on at least part of its length tightly enclosed elongated sensor element ( 1 ), characterized in that the graphite of the sealing body ( 7 ) is a polarized graphite. 2. Gas sensor according to claim 1, characterized in that the sealing body ( 7 ) in the longitudinal direction of the sensor element ( 1 ) between two support bodies ( 3 , 4 ) is clamped. 3. Gas sensor according to claim 2, characterized in that between each support body ( 3 , 4 ) and the sealing body ( 7 ) a layer ( 9 , 10 ) of ceramic powder is enclosed. 4. Gas sensor according to one of the preceding Ansprü surface, characterized in that the sealing body ( 7 ) in the radial direction of the sensor element of egg NEM first ring ( 8 ) is made of electrically insulating Ma material. 5. Gas sensor according to claim 4, characterized in that between the ring ( 8 ) and the inner wall of the bore an outer second ring ( 12 ) is enclosed from a plastically deformable material. 6. Gas sensor according to claim 5, characterized in that the sealing body ( 7 ) and the second ring ( 12 ) are made of the same material. 7. Gas sensor according to claim 4, 5 or 6, characterized in that the first ring ( 8 ) consists of boron nitride. 8. Gas sensor according to claim 4, 5 or 6, characterized in that the first ring ( 8 ) consists of densely sintered ceramic, in particular of steatite or aluminum oxide. 9. Gas sensor according to one of claims 4 to 8, characterized in that the extent of the first ring ( 8 ) in the longitudinal direction is greater than that of the sealing body ( 7 ). 10. A method for producing a gas sensor, in particular a gas sensor according to one of the preceding claims, in which a sensor element ( 1 ) is arranged in a bore in a housing ( 5 ), surrounded by a graphite-containing sealing body ( 7 ) and a pressing pressure on the sealing body ( 7 ) is exercised to cause the sealing body ( 7 ) to tightly enclose the sensor element ( 1 ), characterized in that the sealing body ( 7 ) is formed from a po larized graphite. 11. The method according to claim 10, characterized in that the sealing body ( 7 ) is pre-pressed before it is inserted into the bore. 12. The method according to claim 10 or 11, characterized in that layers ( 9 , 10 ) of ceramic powder are filled into the bore and a pressing pressure of the ceramic powder on the sealing body ( 7 ) is transmitted. 13. The method according to any one of claims 10 to 12, characterized in that a pressing pressure is exerted on the sealing body ( 7 ) by a first ring ( 8 ) made of an electrically insulating material on the peripheral surface of the sealing body ( 7 ) is pushed up. 14. The method according to claim 13, characterized in that a second ring ( 12 ) made of a plastic material, preferably the po larized graphite, is formed and with the release of an annular gap between the second ring ( 12 ) and the sealing body ( 7 ) is inserted into the bore, and that the first ring ( 8 ) is pressed into the annular gap. 15. The method according to claim 14, characterized in that the diameter of the two rings ( 8 , 12 ) and the sealing body ( 7 ) are chosen so that when pressing the first ring ( 8 ) on balance a radi al inward pressure this works.