WO2013120588A1

WO2013120588A1 - Adjustable diffuser for a turbine of an exhaust-gas turbocharger, and turbine for an exhaust-gas turbocharger

Info

Publication number: WO2013120588A1
Application number: PCT/EP2013/000337
Authority: WO
Inventors: Thomas Ihli; Hans-Peter Oehl; Christian Trautmann; Tobias Scheuermann
Original assignee: Ihi Charging Systems International Gmbh
Priority date: 2012-02-17
Filing date: 2013-02-05
Publication date: 2013-08-22
Also published as: DE102012003213A1

Abstract

The invention relates to an adjustable diffuser for a turbine of an exhaust-gas turbocharger, having a first insert part (13) and a second insert part (15) which is arranged so as to lie opposite the first insert part (13), wherein an inflow channel (9) is formed between a first wall (19) of the first insert part (13) and a second wall (20) of the second insert part (15), which second wall (20) is arranged opposite said first wall (19), and wherein a plurality of guide blades (14) for deflecting exhaust gas which flows through the turbine are positioned in said inflow channel (9), and having a spacer element (16) which is positioned in order to ensure a spacing (A) between the first wall (19) and the second wall (20). According to the invention, at least one guide blade (14') of the plurality of guide blades (14) is configured such that it is capable of receiving the spacer element (16).

Description

Adjustable distributor for a turbine of an exhaust gas turbocharger and turbine for a

turbocharger

The invention relates to an adjustable nozzle for a turbine of a

Exhaust gas turbocharger of the type specified in the preamble of patent claim 1 and a turbine of an exhaust gas turbocharger according to claim 7.

An adjustable diffuser is known from the published patent application DE 10 2007 029 004 A1. The adjustable guide serves to change a fluid flow, usually an exhaust gas flow of an internal combustion engine, to a turbine wheel of an exhaust gas turbocharger. The variable nozzle includes a plurality of rotatable vanes positioned between a first insert of the variable nozzle and a second insert of the variable nozzle. With the help of the rotatability of the plurality of vanes, the fluid flow is on the

Turbine wheel can be conditioned. Between a first wall of the first insert part and a second wall of the second insert part, an inflow channel is formed, in which the plurality of guide vanes is arranged. To secure a defined distance between the first wall of the first insert part and the second wall of the second insert part spacer elements between the first insert part and the second insert part are provided. Due to the positioning of the

Distance elements in the flow channel of the fluid flow is opposite to a flow resistance, whereby efficiency losses of the exhaust gas turbocharger are brought about.

The invention is based on the object, an elimination of

Efficiency losses, which due to the positioned in the inflow duct

Spacers occur, with the help of simple measures to bring about and to provide a turbine with reduced efficiency losses. This object is achieved by a guide for a turbine of an exhaust gas turbocharger with the features of claim 1 and by a turbine for a

Exhaust gas turbocharger with the features of claim 7 solved. advantageous

Embodiments with expedient and non-trivial developments of the invention are specified in the remaining claims.

The invention is based on an adjustable guide with a first insert part and a second insert part, wherein between a first wall of the first

Insertion part and one of the first wall opposite to the second wall of the second insert part, an inflow channel is formed, in which a plurality of rotatable vanes and a spacer element are positioned.

According to the invention, a guide vane of the plurality of vanes is the

Spacer element designed receivable. As a result of the fact that the spacer element is arranged at least partially in the guide vane in the inflow channel, it does not constitute a flow resistance in the flow path of the exhaust gas. In other words, the flow resistance in the flow channel is induced exclusively by guide vanes arranged in the flow channel. Thus, pressure losses and consequently

Efficiency losses caused due to positioning of the spacers outside the vane are eliminated. Consequently, there is a reduction in efficiency losses and thus an increase in the efficiency of the exhaust gas turbocharger.

Another advantage of the adjustable nozzle of the present invention is an even distribution of fluid flow induced forces on the variable nozzle, i. in particular to the plurality of vanes.

Between each two adjacently arranged guide vanes of the plurality of

Guide vanes is a flow gap whose size, depending on the setting of the adjustable diffuser, is variable. In other words, each adjustment of the variable nozzle has a certain positioning of the plurality of

Guide vanes, wherein according to the setting of the flow gap between two adjacent vanes between a minimum value and a maximum value is variable. That is, for example, if a large pressure upstream of the turbine wheel is to be achieved with only a small fluid flow mass, the

Flow gap has the smallest value. If a large pressure is to be achieved with a large fluid flow mass, for example when the internal combustion engine is operated at a full load point, the flow gap has the greatest value. For optimal flow of the turbine wheel, it is advantageous if the flow gaps of the adjustable nozzle for a setting each having an equal size. The size of the flow gap is among other things by that of the

Fluid flow induced force on the respective vane influenced. That If different forces are present at the individual guide vanes of the adjustable guide device for adjustment due to different flow resistances, the flow gaps of the adjustable guide device are of different sizes, as a result of which a reduction in the turbine efficiency is ultimately brought about.

Since, according to the invention, only the plurality of guide vanes in the inflow channel effectively position the fluid flow, forces on the adjustable guide device, caused by the fluid flow, are evenly distributed over the adjustable guide vanes, because the same flow conditions prevail in the adjustable guide vanes on all guide vanes. At the same time, this means that adjusting forces for the movement or rotation of the plurality of guide vanes for each of the guide vanes is almost the same, so that for an adjustment the flow gaps between the individual guide vanes are all the same size. This has an increase of

Turbine efficiency directly result. The thus efficient operation of the turbine, and thus of the exhaust gas turbocharger, by the flow loss-reducing design further causes a reduction of fuel consumption and consequently a reduction of C0 ₂ emissions of a standing in connection with the exhaust gas turbocharger internal combustion engine.

In one embodiment of the adjustable guide apparatus according to the invention, a longitudinal axis of the spacer element corresponds to a second axis of rotation of the guide blade. This has both functional and manufacturing advantages. Basically, vanes of the plurality of vanes have a second axis of rotation about which they are rotatably mounted on the first insert part. To ensure the rotatability of the guide vane, in which the spacer element is received, it is advantageous to position the spacer element with its longitudinal axis in the vane, that the vane about the longitudinal axis of the spacer element is rotatable. In terms of manufacturing technology, this means that a fundamentally provided axial opening of the guide vane, which serves to receive a torsion shaft of the guide vane, additionally has one

Recording of the spacer element is used. Accordingly, no additional manufacturing step for the production of the guide vane, which is designed to receive the spacer element provided. In a further embodiment of the adjustable guide apparatus according to the invention, the guide vane is rotatable relative to the spacer element, so that mobility of the spacer element is avoidable, whereby a further securing of the distance between the first insert part and the second insert part can be brought about.

If the guide vane has a sleeve which is arranged coaxially with the spacer element, the guide vane can be moved with the aid of the sleeve, with which the vane is advantageously non-positively and / or positively connected. This offers on the one hand the advantage that a friction-reduced inner surface of the sleeve, which is positioned opposite a lateral surface of the spacer element, can be produced independently of the guide blade. Furthermore, the sleeve may be made of a friction-reducing and high-temperature-resistant material, for example, ceramic, whereas the guide vane is made of the usual high-temperature resistant materials.

In a further embodiment of the nozzle according to the invention that is

Spacer immovably connected at one end to the first insert part and the other end to the second insert part. Thus, a mobility of the spacer element is excluded and ensures the provision of a defined distance between the first part and the second part. A further advantage is that, in addition to the function to ensure a certain distance between the first insert part and the second insert part, a carrier function of the spacer element is brought about, in the sense that the first insert part completely supported and positioned by the spacer element and radially and axially is fixed.

Further advantages, features and details of the invention will become apparent from the following description of a preferred embodiment and from the drawing. The features mentioned above in the description and

Feature combinations as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures are not only in the respectively indicated combination but also in others

Combinations or alone, without departing from the scope of the invention.

The drawing shows in 1 shows a section through a turbine of an exhaust gas turbocharger with a

Guide device according to the prior art,

Fig. 2 shows a detail of an axial section of an inventive

Adjustable diffuser with a vane and a

Distance element and

Fig. 3 is a section through the vane gem. Fig. 2.

A flow-through exhaust-gas guide section 2, shown in FIG. 1, of a turbine of an exhaust-gas turbocharger 1 is located in an exhaust-gas tract of a non-illustrated exhaust

Internal combustion engine, which is a gasoline engine or a diesel engine is provided. The exhaust gas turbocharger 1 also has a not closer

represented by flow-through fresh air guide portion and a bearing section, not shown, which is arranged in a non-illustrated intake tract of the internal combustion engine.

The exhaust gas turbocharger 1 has a running gear 3, which comprises a not-shown compressor wheel for sucking and compressing combustion air, a turbine wheel 4 for expansion of exhaust gas and a compressor wheel with the turbine wheel 4 rotatably connecting shaft 5 having a first axis of rotation 6. The shaft 5 is in

Bearing portion of the exhaust gas turbocharger 1 rotatably mounted, which between the

Air guide portion and the exhaust gas guide portion 2 is positioned.

For the inflow of the exhaust gas into the exhaust gas guide section 2, an inlet channel 7 is formed in the exhaust gas guide section 2. The inlet channel 7 is used to condition the exhaust gas, which puts the turbine wheel 4 in a rotating motion during operation of the internal combustion engine. With the help of the shaft 5, the compressor wheel is also rotated, so that it sucks in combustion air and compressed.

Downstream of the inlet channel 7, a spiral channel 8 is arranged in the exhaust gas guide section 2, which serves to provide a rotationally symmetrical flow. Furthermore, the spiral channel 8 is formed as a connecting channel between the inlet channel 7 and an inflow channel 9, which is positioned downstream of the spiral channel 8. Downstream of the inflow channel 9, a wheel chamber 10 is arranged in the exhaust gas guide section 2, in which the turbine wheel 4 is rotatably received. Downstream of the wheel chamber 10, the exhaust gas guide section 2 has an outlet channel 11 for

Escape of the exhaust gas from the exhaust gas guide section 2.

So that both at low loads and low speeds of the internal combustion engine as well as at high loads and high speeds of the internal combustion engine

the highest possible exhaust-gas turbocharger efficiency can be achieved, the exhaust gas can be conditioned with the aid of an adjustably designed diffuser 12, which in the

Exhaust gas guide section 2 is arranged.

In Fig. 1, an adjustable nozzle 12 is shown according to the prior art. The adjustable guide vane 12, the turbine wheel 4 is formed annularly comprehensive and has a first insert part 13, hereinafter called bearing ring, for receiving a plurality of vanes 14, which is provided for flow conditioning. Each vane of the plurality of vanes 14 is rotatably mounted on the bearing ring 13, wherein each vane of the plurality of vanes 14 is a second

Has rotation axis 18.

The bearing ring 13 is positioned in the exhaust gas guide section 2 such that the plurality of guide vanes 14 is arranged in the inflow channel 9. The bearing ring 13 is positioned opposite a second insert member 15, hereinafter called the contour sleeve, which is designed for flow conditioning and simplified assembly of the nozzle 12. The inflow channel 9 is formed in the region of the adjustable guide apparatus 12 between a first wall 19 of the bearing ring 13 and a second wall 20 of the contour sleeve 15.

For fixing a distance A between the contour sleeve 15 and the bearing ring 13, which is necessary to avoid tilting of the plurality of guide vanes 14 at a rotation about the second axis of rotation 18, spacer elements 16 are positioned in the inflow channel 9. The spacer elements 16 are cylindrical and have a longitudinal axis 17.

The section of an axial section of an adjustable guide apparatus 12 according to the invention, shown in FIG. 2, shows a guide blade 14 'of the plurality of guide blades 14, which is designed to receive the spacer element 16 in an absorbable manner. To accommodate the cylinder-shaped spacer element 16, the guide vane 14 'has a cylindrical opening 21, which extends over an entire axial length L of

Guide vane 14 'is formed extending. For movability of the guide blade 14 ', the longitudinal axis 17 of the spacer element 16 corresponds to the second axis of rotation 18 of the guide blade 14'. So that the movability of the guide blade 14 'is ensured and the guide blade 14' is rotatable relative to the spacer element 16, a first diameter D1 of the opening 21 is greater than a second diameter D2 of the spacer element 16, wherein the first diameter D1 is larger by a minimum clearance MS as the second diameter D2 as shown in FIG.

In an alternative embodiment, not shown, the guide vane 14 'on a non-illustrated, advantageously cylindrical sleeve, which is arranged coaxially with the spacer element 16. The sleeve itself is immovably connected to the vane 14 ', wherein a force, material and / or positive

Connection between the vane 14 'and the sleeve may be provided. In other words, the sleeve is received in the cylindrical opening 21 of the vane 14 ', wherein the sleeve, the spacer element 16 is formed axially partially and radially completely encompassing. The sleeve is advantageously formed over the entire length L extending. Likewise, however, it could also be formed only over a portion of the length L. The sleeve is made of a low-friction material, for example. Ceramic.

The spacer element 16 is at its first end 22, thus at one end, in the bearing ring 13 and at its second end 23, thus the other end, in the contour sleeve 15th

added. For receiving the spacer element 16, the bearing ring 13 has a first receiving opening 24 and the contour sleeve 15 has a second receiving opening 25. The first receiving opening 24 and the second receiving opening 25 can each be designed to penetrate the bearing ring 13 or the contour sleeve 15 completely. In the embodiment shown in Fig. 2, the first receiving opening 24 and the second receiving opening 25, the bearing ring 13 and the contour sleeve 15 is not formed completely penetrating. The spacer element 16 is firmly bonded to the contour sleeve 15 and the bearing ring 13.

Also, for example, the first receiving opening 24 of the bearing ring 13 the

Bearing ring 13 to be formed completely penetrating, whereas the second

Receiving opening 25, the contour sleeve 15 is not formed completely penetrating. Of course, the inversion of the formation of the receiving openings of the

latter embodiment. As an alternative to the cohesive connection, the spacer element 16 can be non-positively and / or positively connected to the bearing ring 13 and the contour sleeve 15.

The adjustable nozzle 12 has to secure the distance A on three vanes 14 'of the plurality of vanes 14, which are each formed a spacer element 16 receivable. Likewise, the number of guide vanes 14 ', which are adapted to receive a spacer element 16, could be greater or smaller than three, but in practice the number of at least three

Distance elements 16 has proven to be sufficient for securing the distance A.

In the exemplary embodiment, the spacer elements 16 are mounted on the bearing ring 13 and the contour sleeve 15. In addition to the function to bring about a constant distance A between the bearing ring 13 and the contour sleeve 15, the spacer element 16 can also be assigned a carrier function, in the sense that the contour sleeve 15 is completely supported and positioned by the spacer element 16 or fixed radially and axially.

Claims

claims

1. Adjustable nozzle for a turbine of an exhaust gas turbocharger, with a

first insert part (13) and a second insert part (15) arranged opposite the first insert part (13), wherein between a first wall (19) of the first insert part (13) and a second wall (20) arranged opposite this first wall (19) of the second insert part (15)

Inflow channel (9) is formed, and wherein in this inflow channel (9) a plurality of guide vanes (14) for discharging the turbine flowing through exhaust gas is rotatably positioned, and with a spacer element (16), which for securing a distance (A) between the first wall (19) and the second wall (20) is positioned,

characterized in that

at least one vane (14 ') of the plurality of vanes (14), the spacer element (16) is designed to be receivable.

2. Adjustable distributor according to claim 1,

characterized in that

a longitudinal axis (17) of the spacer element (16) corresponds to a second axis of rotation (18) of the guide blade (14 ').

3. Adjustable distributor according to claim 1 or 2,

characterized in that

the guide vane (14 ') relative to the spacer element (16) is rotatable.

4. Adjustable distributor according to one of claims 1 to 3,

characterized in that

the guide vane (14 ') has a sleeve which is arranged coaxially with the spacer element (16).

5. Adjustable guide apparatus according to claim 4,

characterized in that

the sleeve is immovably connected to the vane (14 ').

6. Adjustable distributor according to one of the preceding claims,

characterized in that

the spacer element (16) is immovably connected at one end (22) to the first insert part (13) and the other end (23) to the second insert part (15).

7. Turbine for an exhaust gas turbocharger, with an exhaust gas guide portion (2), in which an adjustable nozzle (12) is arranged according to one of the preceding claims.