DE9320985U1 - Metallic honeycomb body with an electrically conductive structure - Google Patents

Description

Application documents to be used as a basis for the registration of the utility model

EMlTCC Society for &ogr;t.06.1995

Emissionstechnologie mbH Ei5637dbm Ka/si/mw

Main Street 150
53797 Lohmar 5

&iacgr;&ogr; Metallic honeycomb body with an electrically conductive structure

The present invention relates to a metallic honeycomb body through which a fluid can flow, with a metallic housing and with an electrically conductive structure that is electrically insulated from the honeycomb body at least in partial areas and is in good thermal contact with the honeycomb body or directly with the fluid, wherein the structure can be connected to a power supply line arranged outside the housing via at least one connection and the connection is guided through the housing in an electrically insulated manner. Honeycomb bodies with such structures are used in particular as electrically heatable catalyst carrier bodies in catalytic converters for cleaning motor vehicle exhaust gases. Such structures are also used as temperature sensors.

For example, heating structures are described in WO 92/02714, where the honeycomb bodies in this document consist practically only of heating structures. For other applications, however, it can also be advantageous to provide separate measuring or heating structures which are in good thermal contact either with the fluid flowing in such a honeycomb body or with the honeycomb body itself. Such arrangements are described, for example, in the unpublished German patent application P 41 29 893.4 or the likewise unpublished German patent application P 42 23 134.5.

These documents mention sheathed conductors as particularly suitable measuring or heating structures. These are electrical conductors that are arranged in a metallic sheath and separated from it by a ceramic, usually powder-like insulation. Such sheathed conductors can be rolled in between two thin sheets of metal. External soldering to thin sheet metal structures or other metallic structures is also possible. Due to the good thermal contact with adjacent metallic structures, a large amount of heat can be introduced into the honeycomb body even via heating conductors with a small cross-section, e.g. less than 1 mm. This is also necessary because electrically heated catalytic converters for motor vehicles, for example, are heated with outputs of 1000 to 4000 watts.

However, a problem arises with the arrangements described in the area of the feedthroughs through the housing and the connections. In this area, the heating conductors or heating structures are no longer cooled by fluid flowing past and by close thermal contact with neighboring metallic structures, so that overheating would occur very quickly in this area if the same resistance per unit length were present there as inside the honeycomb body. At least with a high level of utilization of the heating structures and heating with the maximum possible heat output, the feedthroughs and connection areas would become particularly hot. On the one hand, this is undesirable due to the operational reliability and durability of the arrangement, but on the other hand it is also particularly disadvantageous because copper cables, which oxidize at high temperatures, are usually connected to the connections of the heating structure.

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A similar problem occurs with temperature sensors, namely that the area of the feedthrough, which actually no longer belongs to the measuring range, distorts the measurement because the resistance there also changes with the temperature.

The object of the present invention is to avoid the above-described disadvantages of the prior art and to create a honeycomb body with a measuring or heating structure which does not heat up excessively in the area of the connection and can therefore be reliably connected to copper cables, for example, or which does not cause any changes in resistance in the area of the connection as a function of temperature in temperature sensors, which changes have a strong influence on the measurement.

is To solve this problem, a metallic honeycomb body through which a fluid can flow and which has a metallic housing, in particular an electrically heatable catalyst carrier body for cleaning motor vehicle exhaust gases, with an electrically conductive structure which is electrically insulated from the honeycomb body at least in partial areas and which is in good thermal contact with the honeycomb body or directly with the fluid, wherein the structure can be connected to a power supply line arranged outside the housing via at least one connection and the connection is led through the housing in an electrically insulated manner, wherein the connection and the structure in the area of the connection have a lower resistance than the structure inside the honeycomb body. By reducing the resistance in this area of the structure and at the connection, less ohmic heat is generated there per unit length at the same current strength as in the rest of the structure, so that overheating is avoided when the structure is used as a heating conductor. This is particularly important in the edge area of a honeycomb body, in which

typically there is no such strong cooling by a fluid flowing past. There is also no large-area contact with the housing when passing through a housing, so that heat dissipation is not possible there to the same extent as inside the honeycomb body. By reducing the resistance, i.e. generally by increasing the conductor cross-section, overheating is reliably avoided. When using the structure as a temperature measuring conductor, the area of the connection only influences the measurement very slightly due to its low resistance, so that even temperature changes in this area only distort the measurement slightly.

If the structure is a conductor with a metallic sheath that is electrically insulated from the conductor, the inventive concept can be implemented by having the conductor and the sheath have a larger cross-section in the area of the connection than inside the honeycomb body. The increase in the cross-section must be so great that overheating to critical temperatures cannot occur in the area of the connection or the resistance is reduced to a size that is insignificant for measurement.

In the case of sheathed conductors, the measuring or heating conductor generally has a diameter of 10 to 35% of the outer diameter of the sheath, whereby for the present applications, inner conductors with 15 to 25% of the diameter of the sheath are advantageously used. Such sheathed conductors can be reduced by drawing, hammering or rolling from an originally large diameter to a much smaller diameter, with the length increasing accordingly. Sheathed conductors which have an original sheath diameter of 4 to

8 mm, but are reduced to a diameter of 0.5 to 2 mm in the area between. Particularly favorable values are a diameter of around 5 mm in the area of the connections and a diameter of around 1 mm inside the honeycomb body.

In order to avoid the laborious one-piece production of such sheathed conductors in the desired lengths, it can also be advantageous to weld thicker ends with sheath diameters of 4 to 8 mm to thinner intermediate pieces of 0.5 to 2 mm diameter. However, it is important that the electrical insulation between the inner conductor and the sheathed conductor is maintained. The present invention achieves a further advantage, namely that the ends of the sheathed conductor at the connection have a size suitable for producing a plug connection. The thickened end of the heating conductor at the connection can thus protrude a little from the sheath and be designed directly as a plug for a corresponding connection socket. It is even possible for the sheath at the connection to be provided with an external thread for a union nut. In this case, a commercially available socket with such a union nut can be screwed directly onto the sheath with the protruding inner conductor.

When the sheath of the measuring or heating conductor is passed through the housing, the metallic sheath can be welded to the housing to form a seal, which is important for many arrangements, especially for catalytic converters for motor vehicles.

Usually, a honeycomb body with an integrated measuring or heating conductor is first wound spirally, layered or otherwise intertwined in a conventional manner and then inserted into a housing. In order to create a feedthrough for the measuring or heating conductor

To create this, it is advantageous if the housing has a slot from the front side to the area of the connection, through which the measuring or heating conductor with the jacket can be pushed into the desired position. The housing can then be sealed tightly by subsequently welding the slot and the jacket to the housing. Except for this last step, the production of a honeycomb body with an integrated measuring or heating conductor differs in many cases hardly from the familiar production of metallic honeycomb bodies without a measuring or heating conductor.

If the ends of the structure are led out of the honeycomb body at different points, two connections must of course be provided on the outside of the housing. However, it can be advantageous to lead both ends of the measuring or heating conductor out at a common point and to provide a common connection socket. It is even more advantageous if two measuring or heating conductors that are connected to one another at one end run in a common sheath and are led out through the housing in a common leadthrough. In this case, the effort required for leadthroughs and connections is particularly low.

Embodiments of the invention, to which it is not limited, are explained in more detail below with reference to the drawing.
Fig. 1 is a schematic longitudinal section through a sheathed conductor with thickened ends,

Fig. 2 shows a sheathed conductor rolled between two sheets in cross section,

Fig. 3 schematically shows the U-shaped course of a measuring or heating conductor within a sheet metal layer of a honeycomb body,

Fig. 4 a cuboid honeycomb body made of alternately stacked smooth and corrugated sheets with integrated measuring or heating conductor,

Fig. 5 shows a typical catalyst carrier body with integrated measuring or heating conductor, as can be produced by intertwining a stack of sheets in opposite directions according to Fig. 4.

Fig. 1 shows a sheathed conductor with an inner conductor 1 and a metallic sheath 2, which are separated from each other by an insulating layer 3.

&iacgr;&ogr; are insulated. The inner conductor 1 has thickened ends 4 in which the electrical resistance is considerably lower than in the thin region. The sheath is also thickened in the end regions 5 and has an external thread 6 at the very end. The thickened inner conductor 4 has a piece 7 which projects beyond the thickened sheath 5 and its externally threaded end 6. This protruding piece 7 can be plugged directly into a socket 8 as a plug, whereby the plug connection can be secured by means of the union nut 9 and the external thread 6. The external diameter D in the area of the connections is, for example, 5 mm, while the external diameter d of the sheath inside the honeycomb body can be, for example, about 1 mm. The diameter of the inner conductor 1 or 4 is 15 to 25 %, preferably about 20 %, of the external diameter of the sheath.

Fig. 2 shows schematically how a sheathed conductor can be arranged between two sheets 11, 12. The inner conductor 1 with the surrounding electrical insulation 3 and the outer sheath 2 lies in a bulge 13 of the sheets 11, 12, whereby this shape can be produced, for example, by rolling with elastic rollers. The sheets 11, 12 can be soldered together at the side areas 14 in order to

to increase the stability of the structure. Such an arrangement can also be corrugated by corrugating, so that a measuring or heating conductor can be integrated not only into smooth sheet metal layers, but also into corrugated sheet metal layers.

Fig. 3 shows schematically that a sheathed conductor 2 can also run in a U-shape in or on a sheet metal layer 11, which is advantageous if the connections are to be located close to one another.

&iacgr;&ogr; Fig. 4 shows a schematic representation of a cuboid-shaped honeycomb body 20, which consists of alternating layers of smooth 21 and corrugated 22 sheets. In its interior, a sheathed conductor is integrated between two smooth sheet layers 11, 12, the thickened end 25 of which protrudes laterally. The sheathed conductor 25 in turn runs in bulges 13 of the sheet layers 11, 12. In the present exemplary embodiment, the sheathed conductor 25 has two inner conductors 27, 28, which are preferably connected to one another at their other ends, so that a U-shaped loop is formed overall.

Fig. 5 shows a typical honeycomb body for catalytic converters in motor vehicles, which can be produced from a stack of sheets shown in Fig. 4 by mutually intertwining the ends around two fixed points 33, 34 in a manner known per se. This honeycomb body 30 has a housing 35 which has a slot 31 extending from one end face. A sheathed conductor is again integrated between two sheet metal layers 11, 12 of the honeycomb body 13, the thickened end 5 of which is guided outwards through the housing 35 with an external thread 6 and a protruding piece 7 of the inner conductor. Such a body is produced by first intertwining a body according to Fig. 4 in the opposite direction and then pushing it into the housing 35 from one end face.

The connection 5, 6, 7 is pushed through the slot 31 into the desired position. The slot 31 can then be welded as shown in the drawing, at the same time creating a tight connection 32 between the casing 5 and the housing 35.

The present invention is particularly suitable for the electrical heating of and/or temperature measurement in catalytic converters for motor vehicles. The invention is particularly advantageous in the

&iacgr;&ogr; cases in which a higher voltage than 12 volts is to be used for heating. When heating with 12 volts, high currents are required, which in turn require thick supply lines and relatively complex switching devices. This effort can be partially avoided by heating with a higher voltage, provided that a suitable voltage converter is available.

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Claims (12)

EMITEC Gesellschaft für oi.&ogr;6.1995 Emissionstechnologie mbH Ei5637Gbm Ka/si/mw Hauptstraße 150 53797 Lohmar -^Patent claims 1. Metallic honeycomb body (20, 30) through which a fluid can flow &iacgr;&ogr; with a metallic housing (35), in particular catalyst Carrier body for cleaning motor vehicle exhaust gases, with an electrically conductive structure (1, 4) which is electrically insulated from the honeycomb body (20, 30) at least in partial areas and which is in good thermal contact with the honeycomb body (20, 30) or directly with the fluid, wherein the structure (1, 4) can be connected via at least one connection (5, 6, 7) to a power supply line (8, 9) arranged outside the housing (35) and the connection (5, 6, 7) is guided through the housing (35) in an electrically insulated manner, characterized in that that the connection (5, 6, 7) and the structure (4) in the area of the connection (5, 6, 7) have a lower resistance than the structure (1) in the interior of the honeycomb body (20, 30). 2. Honeycomb body according to claim 1, characterized in that the structure (1, 4) is a conductor (1, 4) with a metallic sheath (2, 5) that is electrically insulated from the conductor (1, 4), the conductor (4) and the sheath (5) in the region of the connection having a larger cross-section (D) than the diameter (d) of the conductor (1) and sheath (2) in the interior of the honeycomb body (20, 30). 3. Honeycomb body according to claim 2, characterized in that the jacket (2, 5) of the conductor (1, 4) is separated from an original diameter (D) of the shell (2, 5) of 4 to 8 mm is reduced to a diameter (d) of 0.5 to 2 mm inside the honeycomb body (20, 30), for example by drawing, hammering or rolling. 4. Honeycomb body according to claim 2, characterized in that the conductor (1) in the interior of the honeycomb body (20, 30) has a sheath diameter (d) of 0.5 to 2 mm, with conductors (4) with sheath diameters (D) of 4 to 8 mm being welded to its ends. 5. Honeycomb body according to claim 2, 3 or 4, characterized in that the end (7) of the conductor (1, 4) at the connection (5, 6, 7) protrudes a little from the jacket (5, 6) and is designed as a plug for a corresponding connection socket (8, 9). 6. Honeycomb body according to claim 5, characterized in that the casing (5, 6) is provided at the connection (5, 6, 7) with an external thread (6) for a union nut (9). 7. Honeycomb body according to one of the preceding claims, characterized in that the conductor (4) with sheath (5) is led out through the housing (35) and the sheath (5) is welded to the housing (35) in a sealing manner. 8. Honeycomb body according to claim 7, characterized in that the conductor (4) with sheath (5) protrudes from the honeycomb body (20, 30) in the region of the connection (5, 6, 7) and is guided outwards through a slot (31) in the housing, the slot (31) running from one end face of the housing to the connection (5, 6, 7) and · after the housing (35) and honeycomb body (30) have been assembled, they are welded. 9. Honeycomb body according to one of the preceding claims, characterized in that two connections (5, 6, 7) are provided for the structure (1, 4). 10. Honeycomb body according to one of claims 2 to 8, characterized in that two conductors (27, 28) which are connected to one another at one end &iacgr;&ogr; are connected, run in a common jacket (25) and are led outwards through the housing in a common passage. 11. Honeycomb body according to one of the preceding claims, characterized in that the structure (1, 4) is a heating conductor for heating the honeycomb body. 12. Honeycomb body according to one of claims 1 to 10, characterized in that the structure (1, 4) is a measuring conductor, in particular a conductor with temperature-dependent resistance for temperature measurement.