WO2016030282A1 - Turbine for an internal combustion engine - Google Patents

Abstract

The invention relates to a turbine (1) for an internal combustion engine. The turbine (1) is arranged in an exhaust gas tract of the internal combustion engine and converts flow energy of a fluid of the internal combustion engine into mechanical energy. The turbine has a turbine wheel (2) with blades (3), and a turbine inlet (4) is arranged upstream of the turbine (1) and a turbine outlet channel (5) is arranged downstream of the turbine (1). The turbine is to be constructed such that the outflow via the turbine wheel is improved. For this purpose, a flow element (6) is arranged at a distance to the turbine wheel (2) on one or more securing elements (7), which are secured to the inner wall of the turbine outlet channel (5), downstream of the turbine wheel (2) such that the flow of the fluid from the turbine wheel (2) into the turbine outlet channel (5) is influenced by the flow element (6).

Description

 description

Turbine for an internal combustion engine

The invention relates to a turbine for an internal combustion engine according to the preamble of claim 1.

Turbines are used in internal combustion engines mainly in the exhaust system to

Flow energy of a fluid of the internal combustion engine, in particular the exhaust gas to convert into mechanical energy. The mechanical energy obtained from the exhaust gas is supplied for example by means of a shaft to a compressor which is assigned to the intake tract of the internal combustion engine and increases the boost pressure of the internal combustion engine. Another example is the further transformation of the mechanical energy into electrical energy, which is then stored or supplied directly to electrical consumers.

The conversion of the flow energy into mechanical energy is done by means of a turbine wheel, which is rotated by the flow. The turbine wheel also represents a disturbance of the flow, wherein the flow must flow around the complex body of the turbine wheel and receives an additional component of motion in the form of a twist by the rotation of the turbine wheel.

An influencing of a flow is also present in a compressor of an internal combustion engine, wherein the energy of the flow is increased by means of a compressor wheel rotated by mechanical energy. From the writings DE 10 2009 014 279 A1 and

WO 2008/155400 A1 discloses devices which are arranged with respect to the flow upstream of a compressor wheel. In this case, the devices have centrally arranged in the flow body, which are characterized by a low flow resistance. These bodies are therefore upstream of the associated wheel and have a tip which is oriented counter to the flow direction.

The document DE 10 2009 014 279 A1 moreover shows a turbine of a

Internal combustion engine, which in the direction of a turbine inlet to a

Turbine outlet channel is interspersed by a flow. The object of the present invention is to build a turbine for an internal combustion engine such that an outflow via a turbine wheel is improved.

This object is achieved by a turbine for an internal combustion engine with the features of claim 1. Advantageous developments of the invention are characterized in the dependent claims.

A turbine according to the invention for an internal combustion engine is arranged in an exhaust tract of the internal combustion engine and converts the flow energy of a fluid

Internal combustion engine into mechanical energy. The fluid is in particular exhaust gas of the internal combustion engine, which is produced by the combustion of fuel with admixture of air in the combustion chambers of the internal combustion engine.

The turbine has a turbine wheel with vanes, upstream of the turbine

Turbine inlet and downstream of the turbine to a turbine outlet channel. The fluid flows into the turbine exhaust passage from the turbine inlet through the blades of the turbine wheel. In this case, the turbine wheel is rotated by the geometric configuration of the turbine blades and thus converted a part of the flow energy of the fluid into mechanical energy, which can be tapped by a shaft on which the turbine wheel is arranged. The turbine wheel may in particular be designed as a radial wheel, wherein the turbine inlet is arranged annularly and radially surrounding the turbine wheel. The turbine wheel can be designed, for example, as an axial or as a mixed form between the radial and axial. The downstream turbine may include a device for aftertreatment of the exhaust gas, in particular a

Oxidation catalyst, be arranged. In this case, the turbine outlet can also be configured as inlet of the exhaust gas aftertreatment device.

Downstream of the turbine wheel is a flow body at one or more

Fasteners arranged. The fasteners are in turn at the

Interior wall of the turbine outlet channel attached. The flow body is disposed substantially centrally in the turbine exhaust passage. In particular, the center of gravity of the flow body has substantially the same distance from the points of the inner wall of the turbine outlet channel lying transversely to the flow direction of the fluid from the center of gravity. For example, the distance to the respective points may differ only by 10% or be exactly the same. Furthermore, a substantially centrally arranged flow body characterized by the fact that the free, the flow available standing cross-sectional area between the inner wall of the turbine outlet channel and

Flow body larger than the largest cross-section of the flow body across the

Flow direction is.

For example, the flow body may have the shape of a projectile in an un-curved turbine exhaust duct. This shape is characterized in that a circular cross-section initially extends axially in a main region with a constant diameter and then terminates in an end region with a convex curvature or even has a substantially round head as the end region. Variations of the shape may be a flat circular area instead of a tip of the end portion or a conical tip of the end portion, a small diameter increase in the main portion, a small reduction in the diameter in the main portion, and / or a deviation from the circular cross section to a small circle be divergent, polygonal or ellipsoidal cross section. The flow body may also have an initial region that characterizes the upstream end of the flow body. Of the

For example, the initial region may be made flat as a flat circular surface or as a substantially round head.

In other cases, when the turbine exhaust duct is curved and / or in the

Diameter widening or decreasing shape, the flow body may be formed such that it is adapted to the shape of the turbine outlet channel.

For example, the flow body may be deformed from the shape of the flow body described for an un-curved turbine exhaust passage; in particular, this deformation may correspond to the deviation of the shape of the turbine exhaust passage from the shape of an un-curved turbine exhaust passage. This means that with a curvature of the turbine outlet channel in one direction, the flow body also has a curvature in this direction, or that with a diameter widening of the turbine outlet channel, the flow body in this flow region

Has cross-sectional enlargement.

A turbine according to the invention has, in the central flow thread, that is to say in the central region of the cross section of the turbine outlet channel, a smaller separation of the flow in comparison to a turbine without flow body. With regard to the flow losses downstream of the turbine wheel, an improvement is achieved by the turbine according to the invention. In particular, a turbine according to the invention, when an exhaust gas purification catalytic converter is arranged downstream of the turbine, brings about an improvement in the flow of the gas Catalyst. Through calculations it has been possible to prove that a turbine according to the invention increases the homogeneity index of the streaming of the catalyst, that is to say that the cross-section of the catalyst is more uniformly flown.

The flow body can optionally be designed as a hollow body or as a solid body. For the selection of materials, there are various materials which fulfill the necessary suitability for a high exhaust gas temperature. Preferably, metallic or ceramic materials can be used due to the high temperatures.

An advantageous embodiment of the turbine according to the invention is that the

Flow body is designed as a rotationally symmetrical body. In this embodiment, the flow body in a plane perpendicular to the flow direction one

circular cross section. The circular cross sections cause very low flow losses and thus represent an additional means, the outflow of the

Turbine to improve further.

Preferably, a central axis of the rotationally symmetrical flow body is identical to a center axis of the turbine wheel. In particular, when the turbine outlet channel has a circular flow cross-section, this can cause the distance of a surface segment of the flow body to be opposite to one another

Surface segment of the inner wall of the turbine outlet channel over the entire circumference of the flow body is constant. The remaining flow cross-section after arrangement of the flow body can thus be formed as a concentric annular cross-section and thus particularly streamlined.

The flow-influencing properties of the flow body can be further improved by the function of a diameter of the flow body over the path along the central axis of the flow body in the flow direction of the fluid monotonously decreasing. In other words, the cross section of the flow body remains in

Flow direction constant or decreases. In particular, in the case of a circular cross section of the turbine outlet channel, this causes the flow cross section remaining in the channel for the fluid to remain constant or increase in the flow direction, whereby the resulting homogeneity of the flow is further increased.

The transition of the flow from the turbine wheel body to the flow body can be particularly even when the largest diameter of the flow body 90 to 105%, in particular 100%, of the smallest diameter of the blades of the turbine wheel with respect to the central axis of the turbine wheel. In this context, since the blades of the turbine wheel usually do not form circular contours around the central axis of the turbine wheel, by the smallest diameter is meant the diameter of the circle formed by the point on a blade of the turbine wheel spaced at the least from the central axis a circle is constructed around the central axis of the turbine wheel.

Radially inward with respect to the blades, turbine wheels usually have a solid hub body to which the blades are connected. Since the hub is formed solid, the turbine wheel is thus flowed through only between the blades of the fluid. By determining the smallest diameter of the blades described above, the radially innermost flow stream in the turbine wheel can be determined. Due to the design of the flow body with a largest

Diameter, which is 90 to 105%, especially 100%, this smallest

Vane diameter is, can be advantageously made possible a largely undisturbed transition of the inner flow threads of the turbine wheel to the flow body.

A further improvement of this transition of the flow from the turbine wheel to the flow body can be achieved in that an axial distance of the flow body to the turbine wheel with respect to the central axis of the flow body is less than 20%, in particular less than 5%, of the largest diameter of the flow body. A gap between the flow body and the turbine wheel represents an unfavorable disturbing contour for the flow, so that the reduction of the gap is expedient for the purposes of the invention.

In order to minimize a negative influence on the flow in the remaining flow cross section, in particular a reduction of the remaining cross section, an advantageous embodiment of the turbine according to the invention is that the fastening elements are designed as struts whose length is at least five times their thickness.

An alternative successful embodiment provides that the fastening elements are designed as baffles whose extension in the flow direction of the fluid is at least four times the extent thereof in the tangential direction to the circumference of the flow body. In other words, the fastening elements are formed as flat bodies which extend in the flow direction. Due to this configuration can actually only for Attachment of the flow body serving elements surprisingly easy to be awarded another function. The planar fasteners serve to reduce a swirl in the flow that has been imposed by the flow through the turbine wheel. The reduction of spin is an additional benefit of high flow homogeneity and low flow losses.

An advantageous design variant of the turbine according to the invention has exactly three fastening elements, which are arranged around the central axis of the flow body at equal angular intervals. This variant provides a good solution to the conflict between filigree fastening elements that keep the flow losses as low as possible, and a sufficiently stable attachment of the flow body. The advantage of this variant is that regardless of the direction of a loading force on the

Flow body at any time at least one of the fasteners is claimed with a low tensile strength with respect to the strength.

According to a further aspect, the invention provides a motor vehicle, which a

Internal combustion engine having a turbine according to the invention, ready.

Further advantages and advantageous embodiments and developments of the invention will be described with reference to the following description with reference to the figures. It shows in detail:

Figure 1 is a sectional view of a first embodiment of an inventive

 turbine

Figure 2 is a side view of the embodiment of Figure 1 from that in Figure 1

 marked viewing direction A

Figure 3 is a sectional view of a second embodiment of an inventive

 turbine

Figure 4 is a representation of a third embodiment of an inventive

 turbine

1 shows a sectional view of a first embodiment of a

Turbine 1 according to the invention. Turbine 1 has a radially arranged turbine inlet 4 and an axially extending turbine outlet channel 5. The fluid of the internal combustion engine flows from the turbine inlet 4 in the direction of the turbine outlet channel 5 and flows through the turbine wheel 2. The turbine wheel 2 has a plurality of blades 3, which are shaped such that the turbine wheel 2 is rotated by the flow about the central axis 9 ,

Downstream of the turbine wheel 2, a flow body 6 is arranged. The flow body 6 is attached to fastening elements 7, which are formed in this embodiment as struts. The fasteners 7 are in turn on the housing wall of the

Turbine outlet channel 5 attached. The flow body 6 is a rotational body whose central axis 8 is coaxial with the central axis 9 of the turbine wheel 2. The flow body 6 is slightly spaced from the turbine wheel 2 and has a diameter which decreases monotonically decreasing in the flow direction until it reaches zero and the flow body 6 ends.

Already explained entities are in the figures, refer to the following embodiments, denoted by the identical reference numerals in Figure 1 and optionally not explained again.

FIG. 2 shows a side view of the embodiment of FIG. 1 from the viewing direction A marked in FIG. 1. The circular shapes are clearly visible

Cross sections of the turbine outlet channel 5 and the flow body 6. The flow body 6 is provided with exactly three fastening elements 7 on the housing wall of the turbine outlet channel

5 attached. The fasteners 7 are evenly distributed angularly, so that in each case for the embodiment shown, an angle of 120 ° between adjacent

Fixing elements 7 is located. The fastening elements are made very thin, so that between the wall of the turbine outlet channel 5 and the flow body 6 as large a flow cross-section remains.

3 shows a sectional view of a second embodiment of a

Turbine 1 according to the invention. The embodiment of Figure 3 differs from that of Figure 1 in that the fastening elements 7 are formed as baffles to take the swirl from the flow. For this purpose, the fasteners 7 are flat and in

Aligned flow direction. A side view of the embodiment according to the figure 3 corresponds by the flat shape of the fasteners 7 exactly the side view of Embodiment of Figure 1, so that the smallest possible reduction of the flow cross-section is caused by the baffles.

FIG. 4 shows a representation of a third embodiment of a turbine 1 according to the invention. Like the preceding exemplary embodiments, the turbine 1 has a

Turbine inlet 4 and a turbine wheel 2 with blades 3 on. The third embodiment shows as a special feature a turbine outlet channel 5, which has both a widening of the diameter and a curvature. Starting from the turbine wheel 2 in the downstream direction, the turbine outlet duct 5 initially widens gradually and then opens in the form of a considerable expansion and curvature into an inlet of an oxidation catalytic converter 10.

The flow body 6 is adapted to this shape of the turbine outlet channel 5. In the downstream direction, the flow body 6 begins with an initial region in the form of a round head. Alternatively, the initial area may additionally have a flattening. Following the initial area, the main area connects, which consists of circular cross-sections and - in adaptation to the turbine outlet 5 - initially increased in cross-section and then tapered again. Also in adaptation to the

Turbinenauslasskanal 5, the flow body 6 is only at the beginning of the main area a rotationally symmetrical body and then follows the curvature of the turbine outlet 5. Finally follows an end portion of the flow body 6, which consists of a conical tip. Alternatively, the end region of the flow body 6 may also be formed as a flat surface, which is parallel to the inlet surface of the oxidation catalyst 10. The entire surface of the flow body 6, with the exception of the areas and / or peaks of the initial region and end region is continuously differentiable. In other words, the surface has no cracks or kinks.

The fasteners 7 are not shown in Figure 4, since these the

Fixing elements 7 can be selected according to the figures 1 to 3 and this has already been adequately addressed in the description associated with these figures. List of references Turbine

turbine

shovel

turbine inlet

Turbinenauslasskanal

flow body

fastener

central axis

central axis

oxidation catalyst

viewing direction

Claims

claims

1. Turbine (1) for an internal combustion engine, wherein the turbine (1) is arranged in an exhaust tract of the internal combustion engine and flow energy of a fluid

 The internal combustion engine converts into mechanical energy, the turbine having a turbine wheel (2) with blades (3) and upstream of the turbine (1) a turbine inlet (4) and downstream of the turbine (1) a turbine outlet channel (5) is arranged,

 characterized in that

 downstream of the turbine wheel (2), a flow body (6), which is arranged substantially centrally in the turbine outlet passage, at one or more

 Fixing elements (7) which are fixed to the inner wall of the turbine outlet channel (5) is attached.

2. Turbine (1) for an internal combustion engine according to claim 1,

 characterized in that

 the flow body (6) is designed as a rotationally symmetrical body.

3. Turbine (1) for an internal combustion engine according to claim 1,

 characterized in that

 the turbine outlet channel (5) has a curved and / or widening or decreasing shape and the flow body (6) is designed such that it is adapted to the shape of the turbine outlet channel (5).

4. A turbine (1) for an internal combustion engine according to claim 2,

 characterized in that

 a central axis (8) of the flow body (6) is identical to a central axis (9) of the turbine wheel (2).

5. Turbine (1) for an internal combustion engine according to claim 4,

 characterized in that

the function of a diameter of the flow body (6) over the path along the central axis (8) of the flow body (6) is monotonically decreasing in the flow direction of the fluid.

6. Turbine (1) for an internal combustion engine according to claim 5,

 characterized in that

 the largest diameter of the flow body (6) is 90 to 105% of the smallest diameter of the blades (3) of the turbine wheel (2) with respect to the central axis (9) of the turbine wheel (2).

7. A turbine (1) for an internal combustion engine according to claim 5 or 6,

 characterized in that

 an axial distance of the flow body (6) to the turbine wheel (2) with respect to the central axis (8) of the flow body (6) is less than 20% of the largest diameter of the flow body (6).

8. Turbine (1) for an internal combustion engine according to one of the preceding claims, characterized in that

 the fastening elements (7) are formed as struts whose length is at least five times the thickness thereof.

9. A turbine (1) for an internal combustion engine according to one of claims 1 to 7,

 characterized in that

 the fastening elements (7) are designed as baffles whose extent in the direction of flow of the fluid is at least four times its extent in the tangential direction to the circumference of the flow body (6).

10. A vehicle having an internal combustion engine with a turbine (1) according to one of the preceding claims.