DE4103083C1 - Steel pipe branch for IC engine exhaust - is formed by integral, hydrostatically shaped component with inner, longitudinal flanges - Google Patents

Abstract

The metal pipe branch assembly has at least one main pipe and two or more branch pipes opening into it. The pipe branch (10) is formed by a cohesive, integral, hydrostatically shaped component which has longitudinal flanges (13) only in the regions on the inside between the branch pipes (15). Each two adjacent branch pipes pref have common longitudinal flanges, which connect the two branch pipes together on their long sides. The branch pipes and the main pipe can have a curved longitudinal path. USE/ADVANTAGE - For i.c. engine exhaust, with precise mfg. possibilities.

Description

The invention initially relates to a metal pipe branch, as he according to the preamble of the claim 1 became known through public prior use is.

The obvious prior use refers to one Steel pipe branch, the basic shape of which is approximately Y-shaped. The known steel pipe branch forms in a motor vehicle internal combustion engine the transition from a main exhaust pipe (exhaust manifold) to two branch pipes, each for a catalyst insert and lead to a silencing system. in the The gusset area between the two branch pipes shows the Metal pipe branch a separate mounting surface for one in the lambda probe protruding into the exhaust gas flow.  

The well-known steel pipe branch consists of two each over the entire circumferential length with radially protruding longitudinal flanges provided deep-drawn or pressed shells. The Longitudinal flanges lying parallel to each other are mutually parallel welded.

In the known metal pipe branch, its manufacturing accuracy perceived as in need of improvement, especially such weldments very susceptible to warping are. With today's automatic manufacturing methods However, it is important to be more precise about workpieces To have manufacturing identity to carry out subsequent processing stages under the same Dimensional accuracy and recurring sequence precisely on workpiece carriers (Workpiece pallets) adjusted and clamped Need to become.

Starting from the known metal pipe branch described above, is the object of the invention, the known Metal pipe branch to a component of precise manufacturing identity to develop further.

This object was achieved in accordance with the invention in the generic metal pipe branch solved that the metal pipe branch from a one-piece material fit contiguous, hydrostatically formed Component is formed, which is only in its areas inside has longitudinal flanges between the branch pipes.

The metal pipe branch according to the invention, which for example consist of a main pipe and two branch pipes can, is characterized in that it waives on welding work or while minimizing welding work  to a factor that does not influence the manufacturing accuracy Made to measure. That is the invention Metal pipe branch from a one-piece material fit connected pipe component manufactured, which on hydrostatic Paths are so visually deformed that only Inside there are longitudinal flanges between the two branch pipes while the outer contour of the entire metal pipe branch has no longitudinal flanges.

According to a first embodiment of the invention two adjacent branch pipes common Longitudinal flanges on which the two branch pipes on the long side connect with each other. Such a design comes about that an output pipe in a central axial section is mechanically pressed in so that the undeformed Main pipe remains at one end and z. B. two branch pipes smaller diameter are preformed. For this first mechanically pressed between two dies Intermediate product is then - if intermediate stages first not be considered - the final metal pipe branch on the way of a hydrostatic deformation within a Die formed. This is a hydraulic pressure medium with a pressure of about 1500 bar into the interior of the intermediate product initiated, which hereby widened experiences the final shape of the die engraving is determined.

According to another embodiment of the invention it is also possible that two adjacent branch pipes at least along their length alongside each other have spaced longitudinal flanges. This embodiment comes about because if necessary the two  Branch pipes connecting longitudinal flanges on the long side recessed (e.g. cut out or punched out), for example in the event that between the two branch pipes an additional assembly or lead-through room is needed.

According to the invention, it is in adaptation to the predominant number of applications in connection with exhaust systems also possible, each with a branch pipe round, especially circular and the main tube with a oval cross-section.

The invention also relates to a method of manufacture a metal pipe branch, which the known Process with which the above-described is evident detach the previously used metal pipe branch should.

The main features of the method according to the invention consist of a metal tube between two Pipe end areas over an approximately extending in the pipe longitudinal direction strip-shaped area to form the longitudinal flanges is mechanically pressed, the pressed tube into a External shape of the pipe branch with its engraving Put in the die and then under hydrostatic internal pressure expanded and nestled against the engraving becomes.

It is important in the method according to the invention that from a metal tube first by mechanical molding e.g. B. within a die, in which both die halves be closed by a press, roughly preformed  is that the basic shape of the metal pipe branch, the e.g. B. should have a main pipe and two branch pipes, recognizable is. This intermediate product is then corresponding the simplest design stage of the invention Process inserted into a die, the engraving of which is already the final shape of the branch pipe determined. That from the die recorded intermediate tube product is then by means of a hydraulic hydraulic fluid with a high hydrostatic Internal pressure applied, thereby expanded and on the engraving nestled so that the metal pipe branch essentially ready. Then z. B. only the two pipe end areas, between which the finished branch structure has arisen to be separated to the To complete the metal pipe branch. This represents a component precise manufacturing identity, which for an automatic - e.g. B. cutting - further processing particularly suitable is.

Another embodiment of the method according to the invention consists in the fact that the metal tube is also diametrical opposite stripes of equal length is pushed in.

As already mentioned, has a metal pipe branch for conventional exhaust systems, a curved longitudinal profile. This is achieved in that the metal tube before mechanical pressing according to the desired one Longitudinal course of the metal pipe branch is bent.

As a rule, metal pipe branches are one require quite a large degree of deformation or expansion before - after mechanical indentation - the final training  inside a die under the effect of hydrostatic internal pressure he follows. In this context, the invention Process before that the metal pipe, if necessary after its Bend, but before mechanical pushing, into a die inserted and expanded under hydrostatic internal pressure becomes. Here, the two pipe end areas adapting to the shape of fittings for introduction of the hydraulic pressure medium. In another The method according to the invention is designed Expansion of the metal pipe then gradually in different dies. It is between each expansion stage a recrystallization annealing (normalizing or normalizing) made by the hydrostatic each time Intermediate deformation eliminates strain hardening becomes.

A particularly interesting manufacturing technology according to the invention Process variant is that between the two tube end areas on two axially spaced apart Pipe areas mechanically indented the metal pipe is so that two pipe branches are preformed, the final hydrostatic shape can be separated.

Overall, it is with the metal pipe branch according to the invention and the inventive method for it Manufactured successfully, a product of high, precise manufacturing identity to create, which at the same time because of the elimination otherwise usual seam connections favorable low vortex flow conditions guaranteed. In addition, the invention Metal pipe branch due to the hydrostatic deformation  an advantageous mechanical in the last stage of production Resilience due to work hardening.

The metal pipe branch according to the invention and the inventive Methods for its production are based on Drawings explained in detail. Here show the

Fig. 1-12 the process steps used in the production of the metal pipe branch, which are also represented side by side in a reduced form for better clarity by Fig. 1a-11a.

In Figs. 1 and 2, 10, such as the starting product is a steel pipe. B. from St 34 or St 37 , shown, the tube longitudinal axis x has a weak S-shaped course. The pipe cross section is circular; the inside diameter is 57 mm throughout. FIG. 2 shows the pipe cross section according to the section line II-II in FIG. 1.

The bent steel tube shown in FIGS. 1 and 2 is inserted into a die (consisting of an upper and lower die) and is expanded hydrostatically from the inside to the outside by introducing a hydraulic pressure medium. The steel tube 10 according to FIGS. 3 and 4 is produced. After this hydrostatic internal pressure deformation, the steel tube 10 has different internal diameters. At the same time, the two tube end regions 11 were formed, which continue to serve the connection to connecting pieces for the introduction of the hydraulic pressure fluid.

Fig. 4 shows the pipe cross section along the section line IV-IV in Fig. 3.

In the area of section line IV-IV and also in Range of an additional double arrow the inside diameter of the pipe 70 mm.

However, the two tube end regions 11 still have a diameter of 57 mm at their outermost points, just as the tube 10 has not yet been expanded or has expanded only slightly in the region of the double arrow M.

The intermediate tube product according to FIGS. 3 and 4 has undergone strain hardening due to its hydrostatic expansion, which is eliminated by normalization in the temperature range of approximately 930 ° C.

5, 6 and 7, 8 is the prerequisite for the expansion stages according to FIGS. 5, 6 and 7, 8. Before each hydrostatic expansion, the tube 10 must therefore be subjected to a normalization at approximately 930.degree.

These expansion stages according to FIGS. 5, 6 and 7, 8 also take place in a separate die in each case by means of hydrostatic internal pressure deformation. And the diameter ratios are readily apparent from FIGS. 5-8.

While the cross section of FIG. 6 is still circular along the line VI-VI in Fig. 5, the hydrostatic internal pressure deformation according to Fig. 8 (the section line VIII-VIII in Fig. 7 respectively) already result in an oval pipe cross-section, which for a mechanical indentation is favorable, which is conceivable with reference to FIGS. 9 and 10.

Specifically, the metal tube 10 is mechanically pressed in between the two tube end regions 11 on two different axial tube regions spaced axially apart from one another via a strip-shaped region 12 running approximately in the longitudinal axis x of the tube to form longitudinal flanges 13 .

This creates a large preform of two successively connected metal pipe branches 18 , each with a main pipe 14 and two branch pipes 15 .

However, FIGS. 9 and 10 show a relation to the not shown rough preform already refined form, which is caused by intermediate hydraulic deformation within a separate die. Partial-cylindrical cylindrical protuberances 16 with flat mounting surfaces 17 are also already provided for the arrangement of one lambda probe each.

The intermediate product according to FIGS. 9 and 10 is then returned to a normalization in a temperature range of approximately 920-930 ° C. and then inserted into a finished die for the final hydrostatic forming, the engraving of which determines the final surface shape of two pipe branches 18 . According to FIGS. 11 and 12, these are still integrally connected to one another at point M. The diameter relations show that the tube workpiece according to FIGS. 11 and 12 ( FIG. 12 shows a cross section corresponding to the section line XII-XII in FIG. 11) has been considerably expanded compared to the intermediate stage of FIGS. 9 and 10 .

In a manner not shown, the pipe cross section at point M in FIG. 11 is also oval. A separation then takes place at point M (for example by sawing), so that two independent steel pipe branches 18 are formed.

Claims (11)

1. Metal pipe branch, in particular steel pipe branch for exhaust systems of internal combustion engines, with at least one main pipe and at least two branch pipes opening into it, pipe areas being arranged by means of longitudinal flanges which are arranged parallel to one another and lie radially from the pipe and are parallel to one another and have an upper flange and bottom flange, characterized in that the metal pipe branch ( 10 ) is formed by a one-piece, cohesively connected, hydrostatically deformed component which has longitudinal flanges ( 13 ) only in its areas inside between the branch pipes ( 15 ). 2. Metal pipe branch according to claim 1, characterized in that in each case two adjacent branch pipes ( 15 ) have common longitudinal flanges ( 13 ) which connect the two branch pipes ( 15 ) to one another on the longitudinal side. 3. Metal pipe branch according to claim 1, characterized in that in each case two adjacent branch pipes ( 15 ) have at least part of their length along the longitudinally spaced longitudinal flanges. 4. Metal pipe branch according to one of the preceding claims, characterized in that branch pipes ( 15 ) and main pipe ( 14 ) have a curved longitudinal profile. 5. Metal pipe branch according to one of the preceding claims, characterized in that the branch pipes ( 15 ) each have a circular, and the main pipe ( 14 ) have an oval cross section. 6.Method for the production of a metal pipe branch, in particular a steel pipe branch for exhaust systems of internal combustion engines, with at least one main pipe and at least two branch pipes opening into it, pipe regions being arranged by means of surfaces which are arranged parallel to one another and radially project from the pipe and are arranged parallel to one another outside the pipe interior Longitudinal flanges, upper flange and lower flange, are connected according to one of claims 1-5, characterized in that a metal tube ( 10 ) between two tube end regions ( 11 ) via a strip-shaped region ( 12 ) running approximately in the longitudinal direction (x) of the tube to form the longitudinal flanges ( 13 ) is mechanically pressed in, the pressed-in tube ( 10 ) into a die representing the outer shape of the tube branch ( 18 ) with its engraving and then expanded under hydrostatic internal pressure and in the process nestled against the engraving. 7. The method according to claim 6, characterized in that the metal tube ( 10 ) at the same time on diametrically opposite equally long strip-shaped areas ( 12 ) is pressed. 8. The method according to claim 6 or according to claim 7, characterized in that the metal tube ( 10 ) is bent before mechanical pressing in accordance with the desired longitudinal profile of the metal pipe branch ( 18 ). 9. The method according to any one of claims 6 to 8, characterized in that the metal tube ( 10 ), optionally after its bend, is inserted into a die prior to mechanical pressing and expanded under hydrostatic internal pressure, the two tube end regions ( 11 ) at the same time Adaptation to the shape of fittings for the introduction of the hydraulic pressure medium are also deformed. 10. The method according to claim 9, characterized in that the hydrostatic expansion of the metal tube ( 10 ) progressively in different dies and between each expansion step, a recrystallization annealing is carried out. 11. The method according to any one of claims 6 to 10, characterized in that between the two tube end regions ( 11 ) on two axially spaced tube regions, the metal tube ( 10 ) is pressed mechanically, so that two pipe branches ( 18 ) are preformed, the be separated from each other after final hydrostatic shaping.