Patent Grant
11268428
This application claims priority to DE 10 2016 106 125.5, filed Apr. 4, 2016.
The present invention relates to an insulating device for a thermal and/or acoustic insulation of an exhaust system of a vehicle. The device has a first half shell including at least a first connection rim and a second half shell including at least a second connection rim, the first half shell and the second half shell being attached to each other at the connection rims.
In addition, the present invention relates to a vehicle exhaust system having an exhaust gas-carrying duct and an insulating device circumferentially surrounding the duct.
The present invention further relates to a method for producing an insulating device for a thermal and/or acoustic insulation of an exhaust system of a vehicle. The device has a first half shell including at least a first connection rim and a second half shell including at least a second connection rim.
It is known in the prior art to provide exhaust systems for vehicles that include, e.g., catalytic converters, diesel particulate filters, mufflers and/or exhaust pipes, with insulating devices. The insulating devices thermally and/or acoustically insulate the components of the exhaust system from an environment. Furthermore, the insulating devices are beneficial to a rapid heating up of, e.g., catalytic converters or diesel particulate filters in the warm-up phase of the vehicle. In this way, the necessary operating temperature for the catalytic converters and the diesel particulate filters is reached faster and the associated efficiency is increased.
The insulating devices are usually made from half shells enclosing the components of the exhaust system which are to be insulated. The half shells are connected with each other by the most varied of methods such as, e.g., welding, clinching, folding or lock seaming.
DE 38 21 468 A1 discloses an insulating device for an exhaust system which can be attached in particular to an exhaust pipe section or a catalytic converter. An insulating mat is placed around an exhaust section and is held by two half shells of a metallic mesh which are connected with each other by the ends of the lower half shell being folded over. To provide protection against moisture, a film or foil may be arranged between the insulating mat and the mesh.
Basically, the aim is always to manufacture insulating devices for vehicle exhaust systems, and vehicle exhaust systems provided with insulating devices, as simply and cost-efficiently as possible. At the same time, the insulating devices and vehicle exhaust systems are intended to take up only a small amount of installation space.
Due to the fact that the presence of water in an insulating device of a vehicle exhaust system significantly reduces the insulating effect, insulating devices are sealed against the ingress of water. Such sealing also needs to be effective when a vehicle passes through water, as can be done by an SUV, for example, and when there is a heavy impact of splash water.
The object of the present invention therefore is to provide an insulating device which can be manufactured cost-efficiently and simply while it is highly watertight.
The present invention provides a generic insulating device in which a first half shell and a second half shell are connected by a welded joint at first and second connection rims, and the connection rims are reshaped into a multiple fold. Here, a multiple fold is defined by the presence of more than the simple folding of only one connection rim, i.e. by at least a simple hemming or folding over of both connection rims. The multiple folding creates a very tight connection of the half shells. Furthermore, the multiple fold also allows very thin half shells to be connected, where a simple fold would not exhibit the required stability. The prior welding process causes the half shells to be positioned in relation to each other, so that folding can be effected with higher precision and the connection rims will not yawn relative to each other at the ends. This is of advantage in particular in the case of very thin half shells.
One embodiment of the invention provides that both connection rims are folded, i.e. bent, more particularly are bent jointly.
The basic idea of the present invention is to make use of very thin half shells, which preferably have a wall thickness of less than 0.2 mm, in an insulating device of an exhaust system of a vehicle, considering that a thin wall thickness always results in a low weight and a simple and cost-efficient processing. In order that a precise positioning and a tight interlocking when folding the half shells can also be ensured with very thin half shells, they are welded to each other. In addition, the connection rims of the half shells are reshaped into a multiple fold which, compared with a simple fold, increases the tightness.
According to one embodiment, the half shells are spot welded at their connection rims. In contrast to a continuous line welding, in this way very thin half shells or half shells having very thin connection rims may also be welded and thus be fixed in place relative to each other.
A further development provides that the multiple fold comprises a first portion in which the two connection rims extend substantially parallel and in particular flat and are welded. Preferably, the connection rims are in direct surface contact with each other. The welded joint is located inside the multiple fold here. Therefore, the insulating device requires only a small amount of installation space.
Advantageously, the multiple fold comprises a second portion in which the two connection rims extend substantially parallel, and in particular flat, with the second portion facing the first portion substantially in parallel and preferably contacting the first portion, and/or preferably being disposed further away from the free ends of the connection rims than the first portion. This means that, proceeding from the free ends of the connection rims, the first portion is located in front of the second portion. Therefore, in a sectional view of the first and second portions, four layers of material of the connection rims lie one on top of the other.
Preferably, the multiple fold comprises a third portion in which the two connection rims extend substantially in parallel, the third portion connecting the first and second portions, the connection rims each being bent by substantially 180° in the third portion to form the multiple fold. In this way, a multiple fold is produced which has a high tightness and stability and in which the connection rims, resting against each other, of the half shells are jointly bent and folded. This allows very thin connection rims or very thin half shells to be processed as well.
Preferably, the connection rims have substantially the same length.
In addition, the half shells may form a pipe, and the connection rim may protrude outward from the pipe. In particular, a free end of a connection rim may, preferably tangentially, contact the outside of the pipe formed by the half shells. The connection rim may protrude outward from the pipe obliquely or at right angles. When the connection rims are folded over by 180°, the free ends thereof point at the pipe. Positioning the free ends in this way allows a simple and safe handling and assembly of the insulating device since thus there are no sharp edges that may protrude from the pipe. Moreover, the tightness is increased by having a further fold.
As an alternative, the half shells may form a pipe and the multiple fold may be oriented tangentially with respect to the outside of the pipe. That is, the multiple fold and the first and second portions thereof extend substantially perpendicularly to a connecting plane of the half shells. The multiple fold requires only a very small amount of installation space.
The first half shell and the second half shell are preferably shaped from a metal foil or sheet metal which preferably have a maximum wall thickness of 0.2 mm. As a result, the half shells are very thin and very light-weight and can be reshaped and worked in a simple manner.
An additional object of the invention resides in providing a vehicle exhaust system which includes an insulating device exhibiting a high water tightness and which is cost-efficient to produce.
The object is further achieved by a generic vehicle exhaust system, the insulating device being designed in the manner set forth above, and an insulating material being disposed between the half shells and the duct.
A further object of the invention resides in providing a method for producing an insulating device for a thermal and/or acoustic insulation of an exhaust system of a vehicle.
The object is achieved by a method of the type initially mentioned, including the steps of attaching the first and second half shells to each other by welding the first and second connection rims; and subsequently bending the first and second connection rims to form a multiple fold.
In one embodiment, in step (a) the two connection rims contacting each other and protruding substantially radially from their half shells are welded together, preferably by resistance spot welding.
In addition, a further development of the method provides that step (b) comprises bending the welded connection rims by substantially 180°, a pipe being formed by the half shells, and the connection rims including a first portion originating from the free ends of the connection rims as well as a second portion contacting the first portion as well as a third portion connecting the first and second portions and bent by substantially 180°. Thus, a multiple fold having three portions is generated, in which the first portion is bent by 180° in relation to the second portion.
Preferably, following step (b) at least one of the connection rims is angled at its free end, and the inner connection rim is placed in position, preferably tangentially placed in position, against the outside of a pipe formed by the half shells at the free end.
In one variant, prior to step (a) an insulating material is disposed between the first and second half shells and a component of the exhaust system.
Preferably, the entire method is performed in a single clamping of the half shells and within a single tool. Therefore, any reclamping or tool changes are not necessary.
According to one embodiment, the radially protruding connection rims contacting each other are angled between two clamping surfaces extending obliquely with respect to a connecting plane of the half shells, one of the clamping surfaces being formed by a first slide feed and an opposing one of the clumping surfaces being formed by a stopper part. The clamping surfaces subsequently continue to clamp this portion of the connection rims, and a second slide feed bends the part of the connection rims protruding with regard to the clamping surfaces before a rail presses the bent, protruding part against the portion of the connection rims previously held between the clamping surfaces with the first and second slide feeds removed. This means that the method proceeds within a single tool without reclamping or retooling.
These and other features may be best understood from the following drawings and specification.
As can be seen in
The vehicle exhaust system 10 is provided with a thermal and/or acoustic insulating device 16 which encloses the duct 12 and the functional element 14 in sections. For reasons of clarity, the insulating device 16 is illustrated in a sectional view and comprises two half shells 18, 20.
An insulating material 22 is disposed between the half shells 18, 20 and the duct 12 and also between the half shells 18, 20 and the functional element 14.
In all of the embodiments of the insulating device 16, it comprises the two half shells 18, 20, which are connected with each other in a connecting plane E.
A connection rim 28 is integrally formed with both opposite edges of the half shell 18, and a connection rim 30 is integrally formed with both opposite edges of the half shell 20, the connection rim protruding laterally from the half shell 18, 20.
The connection rims 28, 30 are connected with each other by a welded joint 24. In the illustrated embodiments of the insulating device 16, the welded joint 24 is in the form of a spot weld.
Additionally, in all embodiments of the insulating device 16, the connection rims 28, 30 are reshaped such that they form a multiple fold 32. The multiple fold 32 comprises three portions.
In a first portion 34 of the multiple fold 32, which starts from the free edges 38, 40 of the connection rims 30 and 28, respectively, the two connection rims 28, 30 extend to be substantially parallel and flat. In this first portion 34, the welded joint 24 is also located.
In a second portion 36 of the multiple fold 32, the connection rims 28, 30 also extend to be parallel and flat. The second portion 36 here faces the first portion 34 substantially in parallel and is directly adjacent to the pipe formed by the half shells. Preferably, the second portion 36 is in direct contact with the first portion 34. For reasons of clarity, a small distance between the first portion 34 and the second portion 36 is depicted in the figures.
The second portion 36 is further away from free ends 38, 40 of the connection rims 30 and 28, respectively, than the first portion 34.
Furthermore, the multiple fold 32 comprises a third portion 42. The connection rims 28, 30 extend substantially parallel in the third portion 42 as well. The third portion 42 connects the first portion 34 with the second portion 36. To this end, the connection rims 28, 30 are bent by substantially 180° in the third portion 42.
In other words, in the third portion 42 the connection rims 28, 30 are folded down once, so that the first portion 34 and the second portion 36 lie directly on top of each other.
The first portion 34, the second portion 36, and the third portion 42 together form the multiple fold 32.
According to the embodiments shown in
The multiple fold 32 may either project perpendicularly from the pipe geometry, as shown in
The angle at which the multiple fold 32 projects from the pipe geometry may be freely selected here. It is preferred, however, as illustrated in
In the embodiments shown in
The embodiments of
Proceeding from the configuration shown in
The embodiment according to
In the embodiments of
In addition to the multiple fold 32 as a whole, the free ends 38, 40 of the half shells 18, 20 may also be aligned and angled. This is illustrated in
Placing the free ends 38, 40 in such a way is illustrated only in
The method for producing an insulating device 16 will be explained with reference to method steps illustrated in
For carrying out the method, a device is made use of which is in the form of a tool, for example, and comprises a stopper part 44 and a holding down clamp 46. The stopper part 44 and the holding down clamp 46 hold the two half shells 18, 20 while the process is in progress. In addition, the device comprises a first slide feed 48, a second slide feed 50, and a rail 52 that are used to produce the multiple fold 32.
In the intermediate state of the process as illustrated in
As is visible in
Then, the first slide feed 48 is moved such that, in cooperation with the stopper part 44, it clamps and bends the two connection rims 28, 30. To this end, a clamping surface 54 is disposed on the first slide feed 48, and a clamping surface 56 is disposed on the stopper part 44. Both clamping surfaces 54, 56 are disposed substantially at that angle at which the two connection rims 28, 30 are to be bent. This means that the clamping surfaces 54, 56 are inclined with respect to the connecting plane E.
In
As can be seen in
In the process, the first portion 34, which also comprises the welded joint 24, is bent up laterally against the first slide feed 48. The actual bending process takes place here in the third portion 42 of the connection rims 28, 30.
As is illustrated in
The first slide feed 48 also returns to its initial position, as can be seen in
Thereafter, the rail 52 moving toward the multiple fold 32 from the outside and obliquely from above further bends the first portion 34 so that the latter contacts the second portion 36. As is apparent from
Additionally, the ends 38, 40 of the connecting portions are placed by the rail 52 against the geometry formed by the half shells 18, 20.
The ends 38, 40 then extend tangentially to the outside of the pipe formed by the half shells 18, 20.
As is apparent when
Although an embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this disclosure. For that reason, the following claims should be studied to determine the true scope and content of this disclosure.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2016 106 125.5 | Apr 2016 | DE | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 3783497 | Griesinger | Jan 1974 | A |
| 3903928 | Sykes | Sep 1975 | A |
| 4333545 | Roberts | Jun 1982 | A |
| 4851298 | Fukuda | Jul 1989 | A |
| 5233832 | Moore, III | Aug 1993 | A |
| 5916137 | Hayashi | Jun 1999 | A |
| 6158547 | Ackermann | Dec 2000 | A |
| 20120273174 | Barnes | Nov 2012 | A1 |
| 20140020785 | Blueml | Jan 2014 | A1 |
| 20180170594 | Speck | Jun 2018 | A1 |
| Number | Date | Country |
|---|---|---|
| 3821468 | Dec 1989 | DE |
| 19825762 | Dec 1998 | DE |
| 202008008690 | Sep 2008 | DE |
| 202008008690 | Oct 2008 | DE |
| 102010025554 | Dec 2011 | DE |
| 102010025554 | Dec 2011 | DE |
| 0556262 | Aug 1993 | EP |
| 2667073 | Nov 2013 | EP |
| 2906307 | Mar 2008 | FR |
| 2913058 | Aug 2008 | FR |
| Entry |
|---|
| Search Report from German counterpart application dated Feb. 1, 2017, plus English summary. |
| Number | Date | Country | |
|---|---|---|---|
| 20170284272 A1 | Oct 2017 | US |
