The invention relates to a resonator insert for coaxial and sectionally radially spaced insertion into an intake pipe of a turbocharger. The resonator insert includes a tube section with a wall having through-slots extending predominantly in the circumferential direction and axially adjacent to one another. The invention further relates to a turbocharger for generating an air flow in a piping system and to a resonator.
Turbochargers are used in vehicles with internal combustion engines to suck in and compress air and to make the air available in large quantities to the combustion process in the cylinders. Noise generated during use of a turbocharger generally is considered a disadvantage. It is therefore known to provide turbochargers with noise reducers that operate on the principle of a Helmholtz resonator. To save installation space, these noise reducers often are integrated in the intake pipe directly in front of the compressor wheel of the turbocharger. The intake pipe of the turbocharger serves as the outer pipe of the resonator, and an inner tube section is arranged coaxially within the intake pipe. The inner pipe is fixed coaxially in the intake pipe by providing reduced diameters at both ends of the intake pipe compared with its central region, and the outer diameter of the inner tube section is adapted to the inner diameter of the narrowed intake pipe ends to form a sealing and mechanically fixing connection, e.g. by pressing or welding. The intake pipe forms an annular chamber surrounding the inner tube section axially between these end sealing areas. The wall of the inner tube section is provided with so-called acoustic slots. The acoustic slots are narrow through-slots through the wall of the inner tube section. More particularly, the acoustic slots extend predominantly in the circumferential direction and are arranged adjacent to one another in a gill-like manner. The acoustic slots can extend perpendicularly or obliquely to the axial direction. The compressor wheel of the turbocharger draws air through the intake pipe during operation of the turbocharger. Sound waves propagating in this air pass through the acoustic slots and into the annular chamber, which also is known as the resonator chamber. These sound waves are superimposed on their own reflections at the chamber walls, resulting in the targeted cancellation of certain sound frequency bands. If the chamber dimensions are matched correctly to particularly strong sound frequencies, there can be a significant reduction in noise, an increase in comfort for the driver of a corresponding motor vehicle and a reduction in external noise pollution.
It has become established practice to implement the resonator by: inserting an insert consisting essentially of the inner tube section with the acoustic slots into a first axial part of an intake pipe that consists of two axial parts, putting on the second axial part of the intake pipe, pressing the second axial part of the intake pipe against the first axial part and connecting the second part of the intake pipe to the first part, e.g. by pressing or welding. This process fixes the tube section of the resonator insert in the final assembly position described above. The intake pipe often is made of aluminum, and the resonator insert frequently is made of plastic, although metallic variants are common.
An expansion of the so-called turbocharger characteristic diagram can be observed in designs where the acoustic slots extend very close to the end of the tube section on the compressor wheel side, i. e. very close to the compressor wheel itself. The turbocharger characteristic diagram describes the area of efficient operability of the turbocharger in the parameter plane formed by the pressure on the one hand and the mass flow on the other. The characteristic diagram is limited on the one hand by the so-called stuff limit and on the other hand by the so-called pump limit. The pump limit describes a minimum mass flow at a given pressure, and at the pump limit there is a flow reversal in the radially outer areas of the intake pipe. This leads to a narrowing of the effective intake cross-section, which in turn further reduces the possible mass flow and intensifies the aforementioned reverse flow. The stuff limit in turn describes the maximum mass flow at a given pressure. A further increase in the mass flow leads to blockages, which in the radially outer area of the intake pipe result in areas of reduced flow velocity, and thus in obstructions in the air flow and likewise in a narrowing of the effective intake cross section.
The use of resonators directly in front of the compressor wheel, which are actually intended primarily for noise reduction, leads to a certain widening of the characteristic diagram because the air masses narrowing the effective intake cross section can escape at least through the acoustic slots that are close to the compressor wheel and into the resonator chamber. Such resonators therefore often also are referred to as pump limit displacement resonators (PLD resonators) in accordance with their actual secondary function.
However, an even greater widening of the turbocharger characteristic diagram would be desirable.
It is an object of the invention to provide devices that broaden the turbocharger characteristic diagram.
One aspect of the invention relates to resonator insert for coaxial and sectionally radially spaced insertion into an intake pipe of a turbocharger. The resonator insert in accordance with this aspect of the invention has a tube section with a wall having through-slots extending predominantly in the circumferential direction and axially adjacent to one another. The wall of the tube section carries at least one radially outwardly directed, axially extended lamella crossing the through-slots.
Another aspect of the invention relates to turbocharger for generating an air flow in a piping system. The turbocharger according to this aspect of the invention includes a rotatable compressor wheel and an intake pipe located directly upstream of the compressor wheel in the direction of air flow, with reduced pipe cross-sections at both ends. The turbocharger in accordance with this aspect of the invention further has a resonator insert arranged coaxially in the intake pipe. The resonator insert has a tube section that terminates sealingly with the ends of reduced cross-section of the intake pipe and has in its wall a plurality of through-slots in the wall thereof. The through-slots extend predominantly in the circumferential direction and are axially adjacent to one another and via which the interior of the tube section is connected to a resonator chamber formed between the tube section wall and the wall of the intake pipe.
The tube section of at least certain embodiments carries at least one radially outwardly directed axially extended lamella crossing the through-slots.
The resulting, functional resonators are not limited to use in the context of turbochargers. Therefore, a resonator as described herein where the wall of the inner tube section carries at least one radially outwardly directed, axially extended lamella crossing the through-slots constitutes an independent aspect of the present invention.
In a kinematic reversal of this idea, an aspect of the invention also relates to a resonator where the wall of the outer pipe carries at least one radially inwardly directed, axially extended lamella crossing the through-slots.
The invention is based on the realization that the air masses escaping into the resonator chamber form an annular flow in the resonator chamber, and the annular flow circulates around the (inner) tube section. This movement causes at least parts of these rotating air masses to penetrate back out of the resonator chamber through the acoustic slots and then cause a narrowing of the effective cross-section of the intake and of the flow. The lamella of the invention prevents or significantly reduces this harmful annular flow. As a result, the air masses in question are distributed along the axially extended lamellae and do not penetrate back out of the resonator chamber, or merely not to such an extent or distributed over the axial length of the inner tube section.
In some embodiments, the wall of the inner tube section further carries an annular wall that is directed radially outwardly, is annular disc-shaped, and is oriented perpendicular to the axial direction. This annular wall thus divides the resonator chamber into two axial sections that can act as separate resonator chambers. If the radial height of the annular wall is designed to rest against the wall of the outer pipe of the resonator or the intake pipe of the turbocharger, the two axial annular chamber sections or the two annular chambers are sealed against each other. However, the separation of the axial annular chamber sections by the annular wall may be incomplete, since at least some areas of the annular wall have a reduced radial height compared to the wall spacing between the (inner) tube section and intake pipe or outer pipe. The result is two interacting resonator chambers. The skilled person will recognize that the arrangement of more than one annular wall with a corresponding increase in the number of resonator chambers is also possible.
It is possible that the annular wall is arranged in the axially central area of the (inner) tube section and that the through-slots are arranged on only one axial side of the annular wall. In particular, the through-slots should be arranged on the compressor wheel side of the ring wall. As explained above, the additional widening of the characteristic diagram according to the invention occurs especially when the effective area of the resonator, i. e. the axial area in which the acoustic slots are arranged, is as close as possible to the compressor wheel.
The skilled person has a wide variety of possible shapes of the lamellae according to the invention, and some of the preferred shapes will be explained below. They all have in common that they are suitable for achieving the above-described effect of preventing or at least obstructing the annular flow in the resonator chamber and thus reducing the harmful constriction of the effective intake cross-section.
In a first embodiment, the radially outer edge of the lamella rests against the wall of the intake pipe or outer pipe. With this embodiment, the possibility of annular flow in the resonator chamber is prevented completely over the entire axial length of the intake pipe or outer pipe, or at least over its length from its end to a sealing annular wall that may be provided.
Alternatively, the radially outer edge of the lamella can be spaced at least in sections from the wall of the intake pipe or outer pipe. In this embodiment, annular flow remains possible in principle, but is significantly obstructed. Embodiments with a sealingly abutting annular wall are configured so that the radially outer edge of the lamella is at a lower radial height than the radially outer edge of the annular wall or so that the radial height of the radially outer edge of the lamella varies over its length. The above variants differ essentially in their acoustic effects. The person skilled in the art will therefore make a choice in view of the overall result desired in each case.
The skilled person can also vary the axial extension of the lamella according to the invention. Preferably, the lamella extends in the axial direction from a free end of the tube section, namely the end on the compressor wheel side, to the annular wall—if present. In this way, a truly complete interruption of the resonator chamber and thus of the disadvantageous annular flow can be achieved. The same applies, of course, in the case of a missing annular wall when a lamella is used which extends over the entire length of the resonator chamber, i.e. the (inner) tube section.
The lamella can have one or more through-holes, and in some embodiments, the lamella has several circular through-holes of different diameters. The number and size of the circular holes are selected to achieve a particularly precise tuning of the acoustic effects of the lamella.
Alternatively, the lamella can have precisely one passage opening that occupies the major part of its lamella surface, so that the lamella is reduced to a bow arching over the passage opening. This bow can rest against the wall of the intake pipe or the outer pipe. This embodiment has a smaller reduction in the annular flow. However, the acoustic properties such a resonator differs very little from conventional resonators with otherwise identical dimensions.
Plural lamellae can be distributed over the circumference of the (inner) tube section. These lamellae can be of the same design or of different designs. The provision of several lamellae leads to an even greater interruption of the resonator chamber in the circumferential direction, which also prevents the formation of small-scale vortices that can have a similarly detrimental effect as the circumferential ring flow described above.
The above explanations also apply mutatis mutandis to embodiments in which the lamella or lamellae are not or not only fixed to the (inner) tube section, i. e. are part of the resonator insert, but to the outer pipe. In the specific context of turbochargers, this will generally be impractical in terms of production technology, although by no means impossible; for resonators in general, including the specific application in the context of a turbocharger, however, such variants are certainly conceivable alternatives.
Further details and advantages of the invention will be apparent from the following specific description and drawings.
Like reference signs in the figures indicate like or analogous elements.
The present invention is aimed at preventing annular flow in the resonator chamber 18. To this end, in the embodiment shown, two opposed lamellae 144 extend radially out from the tube section 141, as shown in
In the embodiment shown, the tube section 141 is surrounded by an annular wall 145 that is perpendicular to the axial direction and has the same radial height as the lamellae 144. Thus, the annular wall 145 rests with its radially outer edge against the intake pipe 12 or outer pipe 121 and divides the annular chamber 18 into two axial sections separated from each other. In the embodiment shown, however, only the axial section on the left in
In the embodiment of
The situation is reversed in the embodiment shown in
In the embodiments of
Finally,
Of course, the embodiments discussed in the specific description and shown in the figures are only illustrative examples of embodiments of the present invention. The person skilled in the art is provided with a wide range of possible variations in light of the present disclosure. In particular, the specific dimensioning of the individual components of the resonator insert according to the invention must be adapted to the acoustic and characteristic field requirements of the individual case. With regard to the choice of materials used, in particular metal and/or plastic, the person skilled in the art will also know how to orient himself to the requirements of the individual case.
Number | Date | Country | Kind |
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10 2021 103 379.9 | Feb 2021 | DE | national |
Number | Name | Date | Kind |
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8197188 | Clay | Jun 2012 | B2 |
8408357 | Cheung | Apr 2013 | B2 |
11391252 | Gautam | Jul 2022 | B2 |
20200340497 | Lombard et al. | Oct 2020 | A1 |
Number | Date | Country |
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199 43 246 | Mar 2001 | DE |
Number | Date | Country | |
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20220260045 A1 | Aug 2022 | US |