DE4224499A1 - Flange connection between two exhaust gas pipes - has thermal insulation between inner gas pipe and flange and outer pipe to reduce temp. of the flange. - Google Patents

Abstract

The inner gas-conveying pipe (5) of the pipe element (1) comprising an outer (3) and inner (5) pipe is thermally insulated at its end associated with the flange (4) from the outer pipe (3) and the associated flange (4). The inner pipe can have in the flange area over the entire circumference a radial distance (6) from the outer pipe and/or flange. The inner pipe can be held centred in the flange area relative to the outer pipe and/or flange by a ring element (7). The inner pipe axially protrudes over the connecting point between the two pipe elements (1,2). USE/ADVANTAGE - Flange connection is esp. for pipe connections where the outer pipe is designed for support and the inner pipe is made of thinner material intended only to convey gas.

Description

The invention relates to a flange connection between two exhaust gas-carrying parts, in particular pipe elements, of which at least one tubular element from a ver with a flange bindable outer tube and a radial distance inside supported inner gas-carrying pipe is constructed.

It is known to have exhaust pipes made of two nested Manufacture pipes between which there is an insulation gap is present (US-PS 35 81 494). The insulation gap can air filled or filled with an insulating material. Because of the insulation gap, the outer tube remains significantly cooler than the inner tube. The connection of such exhaust pipes with  happens to each other or for example with an engine block via flange connections. In the area of the flanges is each the inner tube to the flange and / or the outer tube leads and welded to it if necessary. The isolation there is no gap in the area of the flanges. This also applies in the event that a in the area of the flange Sliding seat is available, so the inner tube only on the Au the outer tube or the flange but is not connected, so that it can still move axially. The absence of the Air gap thus leads to the formation of a thermal bridge an increase in the temperature of the flange itself and the Outer pipe leads in this area.

The invention has for its object a flange connection to create a reduction in temperature of the flange and the outer tube in the flange area.

To achieve this object, the invention proposes a flange connection with the features of claim 1. Continuing Applications are the subject of the subclaims.

The thermal insulation between the hot inner tube on the one hand and the flange and the outer tube also in the area the flange connection means that the flange itself is a has lower temperature. This increases the Fe strength of the flanges or you can with the same strength thinner flanges or flanges made of less expensive material use. With thinner flanges this is also reduced Weight. In addition, the heat radiation in the reverse exercise is reduced, which is particularly important is when motors are broken due to restrictive regulations must be rare.  

One possibility of thermal insulation is fiction according to the continuation of the radial distance between the outside tube and the inner tube.

If the radial distance of the inner tube is also maintained In the end area, according to the invention, further training can be provided hen be that the inner tube in this area compared to the outer tube and / or the flange is centered. This centering can U. can be very advantageous, in particular the more complicated forms, the stronger ones Longitudinal expansion of the warmer inner tube compared to the outside pipe can also lead to a lateral displacement. A lateral concern then still occurs isolation in all other areas, however Centering also improves insulation in this case bring. For example, a centering around the Pipe end placed ring made of wire mesh or another Serve material. Centering is also conceivable caused by beads on the inner tube and / or outer tube.

According to the invention it can be provided in a further development that axially forward the inner tube through the flange joint jumps and protrudes a little into the other tube.

In a further development of the invention it can be provided that the second pipe element double-walled from an outer and an inner tube is built, the inner tube is flat if a radial distance from the outer tube and / or the Has flange.

In a further development it can be provided that the two inner tubes in the area of the flange connection Form sliding seat. The sliding seat is of a flat  The two tubes rest against each other, however a shift in the axial direction is possible.

According to the invention it can be provided that the sliding seat Centering for at least one of the two inner gas guides forming pipes.

The invention can flange connections between any form gas-carrying pipe parts, for example with advantage a flange connection between an exhaust manifold and a down pipe.

But it is also advantageous for a flange connection between a down pipe and a catalyst housing bar.

In particular, the flange connection during attachment of the exhaust manifold are applied to the cylinder head. So can, for example, around the exhaust port in the cylinder head be arranged around an annular groove, in the assembly zen the inner gas pipe of the exhaust manifold takes hold. In this case, too, is the inner gas pipe of the exhaust manifold thermally from the flange of the exhaust manifold and the flange of the cylinder head uncoupled.

The invention is particularly applicable to pipe connections bar, in which the outer tube has the supporting function takes and the inner tube of thinner material only to Gas flow serves.

But it is also applicable in cases where the Inner tube in addition to the gas duct also the load-bearing one Function.

Further features, details and advantages of the invention he derive from the patent claims, the wording of Reference is made to the content of the description following description of preferred embodiments of the Er and the drawing. Here show:

Figure 1 is a schematic longitudinal section through the junction of two tubular elements.

Fig. 2 shows a flange connection between two pipe elements, of which only one is double-walled;

Fig. 3 is a representation corresponding to FIG. 2, in which both tubular elements are bilayer ausgebil det.

In Fig. 1, a connection between a pipe element 1 shown on the right and a pipe element 2 shown on the left is provided. The tubular element 1 has an outer tube 3 , which is provided in its end region with a flange 4 , which is welded to the outer tube 3 , for example. Inner half of the outer tube 3 , an inner tube 5 is arranged, which is held concentrically with the outer tube. So it has a radial distance 6 from the outer tube 3 everywhere. For centering, a ring element 7 made of a wire is arranged between the outer and inner tubes 3 and 5 in the end region. The inner tube 5 , which consists of thinner material, projects beyond the free end face 8 of the flange 4 .

The second tube element shown on the left in FIG. 1 also contains an outer tube 9 which is connected in its end region to a flange 10 , for example welded.

The flange 10 corresponds in shape and dimension to the flange 4 in wesentli chen. Also in the outer tube 9 of the second tubular element 2 is an inner tube 11 made of thinner material so on arranged that it ßenrohr all sides a radial distance 12 from the Au has. 9 In its end region, the inner tube 11 is somewhat expanded, so that the expanded end region 13 fits over the end of the inner tube 5 of the first tube element 1 and forms a sliding fit with it. The sliding seat is essentially gas-tight, so that the hot exhaust gas remains beyond the flange connection shown within the space formed by the inner tubes 5 , 11 .

Between the two flanges, a seal 14 is net angeord. The two flanges can be connected to one another, for example, by screwing.

Due to the thermal insulation of the inner tube 5 , 11 shown, both from the flanges 4 , 10 and from the outer tubes 3 , 9 in the area of the flange connection shown, the flanges and outer tubes remain rich in this loading area cooler than the inner tube.

While the illustration of FIG simplified. 1 and was schematically, Fig. 2 shows another flange joint in which a tubular member is an exhaust manifold 15 and the pipe to be connected with this element, a head pipe sixteenth The front pipe 16 leads to a catalyst.

The flange 4 is welded to the outer pipe 3 of the exhaust manifold 15 . The flange 4 has a stepped shape in the area of its inner opening, so that the outer tube 3 can first be inserted there before the welded connection takes place. So there is a smooth continuous opening opening. Also in the case of FIG. 2, the inner tube 5 of the exhaust manifold 3 projects beyond the corresponding end of the flange 4 . Again, there is a radial distance 6 between the inner tube 5 on the one hand and the flange 4 or the outer tube 3 on the other hand.

The front tube 16 is designed as a single tube, so it does not contain an inner tube. In its end area it is expanded in a funnel shape. The associated flange 10 is pushed onto the front pipe 16 and bears against the widening region of the front pipe. The connection between the flange 10 and the front pipe 16 is thus established when the two flanges 4 , 10 are screwed or clamped together. In the embodiment shown in FIG. 2, the inner pipe 5 of the exhaust manifold 15 extends to the other end of the flange 10 associated with the down pipe 16 , and also has a radial distance 6 in this region. The front pipe 16 is therefore only fully hit by the exhaust gas in a region downstream of the end of the inner pipe 5 of the exhaust manifold 15 .

The inventor of the present application has found that even with this only partially effective thermal decoupling, the distance reduces the temperature of the flanges 4 , 10 by about 50 °.

Fig. 3 now shows an embodiment in which the front tube 16 is also double-walled from an outer tube 9 and an inner tube 11 is constructed. The end of the exhaust manifold 15 is identical to the representation of FIG. 2, so that the off is not explained puffkrümmer 15 again. The inner tube 11 of the front tube 16 in this case has a slightly larger diameter than the inner tube 5 of the exhaust manifold 15 , so that the two tubes can be placed on top of one another and thus form a sliding fit. The centering of the inner tube 11 in the front pipe 16 is effected here by the sliding seat with the inner pipe 5 of the exhaust manifold 15 , so that no separate centering within the front pipe 16 is required.

In the embodiment shown in Fig. 3 Tem temperature reductions in the range of 100 ° could be achieved.

Claims (12)

1. Flange connection between two exhaust gas-carrying parts, in particular tubular elements ( 1 , 2 ), of which at least one tubular element ( 1 ) from an outer tube ( 3 ) which can be connected to a flange ( 4 ) and an inner one held at a radial distance ( 6 ) gas-carrying pipe ( 5 ) is constructed, characterized in that the inner pipe ( 5 ) in the region of its flange ( 4 ) associated end of the outer pipe ( 3 ) and the associated flange ( 4 ) is thermally insulated. 2. Flange connection according to claim 1, wherein the inner tube ( 5 ) in the region of the flange ( 4 ) substantially over the entire circumference has a radial distance ( 6 ) from the outer tube ( 3 ) and / or the flange ( 4 ) . 3. Flange connection according to claim 1 or 2, wherein the inner tube ( 5 ) in the region of the flange ( 4 ) with respect to the outer tube ( 3 ) and / or the flange ( 4 ) is centered. 4. Flange connection according to claim 3, in which a ring element ( 7 ) is provided for centering. 5. Flange connection according to one of the preceding Ansprü surface, in which the inner tube ( 5 ) on the connection point between the two tubular elements ( 1 , 2 ) projects axially. 6. Flange connection according to one of the preceding claims, in which the second tubular element is constructed from an outer tube ( 9 ) which can optionally be connected to a flange ( 10 ) and an inner gas-carrying tube ( 11 ) held therein with a radial distance ( 12 ) and the inner tube ( 11 ) in the region of its flange ( 10 ) zugeordne th end of the outer tube ( 9 ) and the associated flange ( 10 ) is thermally insulated. 7. Flange connection according to claim 6, wherein the thermal insulation of the second tube element ( 2 ) is formed by a radial distance between the inner tube ( 11 ) and the outer tube ( 9 ) or the associated flange ( 10 ). 8. Flange connection according to claim 6 or 7, wherein the two inner tubes ( 5 , 11 ) form a sliding fit in the region of the flange connection. 9. Flange connection according to claim 7, wherein the sliding seat forms a centering for the inner tube ( 11 ). 10. Flange connection according to one of the preceding claims, in which a pipe element ( 1 ) is an exhaust manifold ( 15 ) and the second pipe element ( 2 ) is a front pipe ( 16 ). 11. Flange connection according to one of claims 1 to 9, in which a tube element ( 2 ) is a down tube ( 16 ) and the second tube element is a catalyst housing. 12. Flange connection according to one of claims 1 to 9, wherein a pipe element ( 1 ) is an exhaust manifold ( 15 ) and the second pipe element is a cylinder head of an engine block.