The present invention relates to a diffuser for a radial compressor. The designation radial compressor below also comprises what are known as mixed-flow compressors with an axial inflow and a radial outflow of the compressor impeller. The field of application of the present invention also extends to compressors with a purely radial or diagonal inflow or outflow of the compressor impeller. The present invention furthermore relates to a diffuser for a radial compressor, wherein the radial compressor can be used in a turbocharger, and wherein the turbocharger can have an axial turbine or a radial turbine or what is known as a mixed flow turbine.
Diffusers for use in radial compressors for turbocharger applications are known from the prior art. In a radial compressor, a fluid, for example, air, is firstly sucked in axially via a compressor wheel connected upstream of the diffuser and accelerated and pre-compressed in the compressor wheel. Energy which is present in the form of pressure, temperature and kinetic energy is supplied to the fluid. High flow speeds prevail at the outlet of the compressor wheel. The accelerated and compressed air leaves the compressor wheel tangentially in the direction of the diffuser. Kinetic energy of the accelerated air is converted into pressure in the diffuser. This occurs by way of a deceleration of the flow in the diffuser. The flow cross-section of the diffuser is increased in size as a result of radial expansion. The fluid is thus decelerated and pressure is built up.
In order to achieve as high as possible pressure conditions in a turbocharger with a radial compressor, the diffusers used therein can be provided with a blading. DE 10 2008 044 505 shows an example of a bladed diffuser. The diffusers known from the prior art with blading are generally formed as radial parallel-walled diffusers with blading, such as shown, for example, in U.S. Pat. No. 4,131,389. In order to achieve a higher compressor efficiency at a given overall pressure ratio, the flow in the diffuser can be delayed to a greater extent. The flow speeds in the spiral are reduced as a result of this, as a result of which the wall friction losses are reduced and the efficiency of the compressor stage is improved.
It is known from the prior art that the use of diffusers with radial side wall divergence enables a greater deceleration with the same structural length in comparison with parallel-walled diffusers.
The deceleration or increase in pressure which can be achieved in the diffuser by geometrical variation for a given operating point is, however, restricted since flow instabilities arise in the case of excessive deceleration as a result of boundary layer detachment in the diffuser. The limits of the stable operating range of the diffuser thus determine the position of the surge limit of the compressor in the compressor characteristic diagram. If, instead of a parallel-walled diffuser, a diffuser with side wall divergence is used—such a diffuser is described, for example, in WO 2012/116880 A1—the efficiency is indeed increased in the case of the same compressor pressure ratios, but at the same time the surge limit for a given compressor pressure ratio is displaced in comparison with the compressor with a parallel-walled diffuser towards greater mass flows. This effect is undesirable. The compressor characteristic diagram width is reduced as a result of this and the usability of the compressor stage for applications in the turbocharger is restricted as a result of this.
One solution lies in fluidically connecting a diffuser channel portion of a bladed diffuser via pressure-equalizing openings to an annular channel in order to enable pressure equalization between individual diffuser passages of the diffuser which are formed by adjacent diffuser vanes. However, in the case of this solution using pressure-equalizing openings, the problem can arise that the annular channel and/or the individual pressure-equalizing openings block, for example, as a result of residues and deposits from compressor cleaning or by particles which are located in the oil-containing intake air. This has a negative influence on the surge limit of the compressor and can in extreme cases lead to it no longer being possible to operate a motor connected to the diffuser.
WO 2016/102594 discloses a diffuser for a radial compressor in the case of which the above-mentioned problem does not arise. This diffuser has a diffuser channel portion which is formed by a first side wall and a second side wall, wherein the first side wall and the second side wall are arranged at least partially divergently to one another in the direction of flow. The diffuser furthermore comprises a vane ring with a number of vanes, wherein the vanes are arranged at least partially in the diffuser channel portion, and wherein each of the vanes has a pressure side and a suction side. The pressure side and the suction side of each vane are delimited by a vane inlet edge and by a vane outlet edge of this vane. The diffuser furthermore comprises a number of pressure-equalizing openings which are incorporated in at least one of the two side walls of the diffuser channel portion, wherein each of the number of pressure-equalizing openings is arranged between the pressure side of a vane and the suction side of the adjacent vane of the vane ring. The diffuser furthermore comprises an annular channel which is arranged behind the pressure-equalizing openings, wherein the annular channel is fluidically connected to the diffuser channel portion via the pressure-equalizing openings. The annular channel can be connected via a connecting channel to a pressure plenum, as a result of which a fluid can flow from the pressure plenum into the annular channel so that the annular channel is rinsed with the fluid. Such a structure has the advantage that potential deposits and residues from carbonization by oil-containing intake air which could block the annular channel and the pressure-equalizing openings are rinsed out of the annular channel and thus also out of the pressure-equalizing openings by way of the fluid which is formed as a rinsing medium and which flows out of the pressure plenum into the annular channel in order to rinse out the annular channel with fluid.
The object on which the present invention is based is to further develop a bladed diffuser in such a manner that its operating range is increased.
This object is achieved by the diffuser with the features indicated in claim 1. Advantageous configurations and further development of the invention are indicated in the dependent claims.
A diffuser according to the invention has a flow channel which is delimited by a first side wall and a second side wall, a diffuser vane ring with a plurality of diffuser vanes which are arranged at least partially in the flow channel, wherein each of the diffuser vanes has a pressure side and a suction side, a plurality of diffuser passages, wherein these diffuser passages are formed between in each case two adjacent diffuser vanes of the plurality of diffuser vanes, and circulation openings, wherein each of these circulation openings connects the flow channel to a diffuser cavity and wherein at least two circulation openings are assigned to a diffuser passage, which circulation openings are fluidically connected to one another via the diffuser cavity.
The term diffuser passage refers to the region between two adjacent diffuser vanes which is determined on the inlet side by the vane inlet radius circle and on the outlet side by the vane outlet radius circle. A circulation opening assigned to a diffuser passage can be positioned within the diffuser passage, in front of the diffuser passage or behind the diffuser passage.
According to one embodiment of the present invention, the circulation openings assigned to a diffuser passage are arranged at different positions in the direction of flow.
According to one embodiment of the present invention, the circulation openings assigned to a diffuser passage are arranged next to one another in the direction of flow.
According to one embodiment of the present invention, in each case two or more circulation openings which are connected to one another via the diffuser cavity are assigned to all diffuser passages or only some of the diffuser passages.
According to one embodiment of the present invention, at least one circulation opening assigned to a diffuser passage is positioned upstream of the narrowest point of the diffuser passage and at least one further circulation opening assigned to the diffuser passage is positioned downstream of the narrowest point of the diffuser passage.
According to one embodiment of the present invention, the number of circulation openings positioned upstream of the narrowest point of the diffuser passage is greater than or equal to the number of circulation openings positioned downstream of the narrowest point of the diffuser passage.
According to one embodiment of the present invention, at least one of the circulation openings positioned upstream of the narrowest point of the diffuser passage is arranged within the diffuser passage between the pressure side of a diffuser vane and the suction side of an adjacent diffuser vane.
According to one embodiment of the present invention, at least one of the circulation openings positioned upstream of the narrowest point of the diffuser passage is positioned in front of the inlet of the diffuser passage in the direction of flow, wherein the inlet of the diffuser passage is determined by the vane inlet radius circle.
According to one embodiment of the present invention, at least one of the circulation openings positioned upstream of the narrowest point of the diffuser passage is positioned within the diffuser passage between the pressure side of a diffuser vane and the suction side of an adjacent diffuser vane and at least one further of the circulation openings positioned upstream of the narrowest point of the diffuser passage is positioned in front of the inlet of the diffuser passage in the direction of flow, wherein the inlet of the diffuser passage is determined by the vane inlet radius circle.
According to one embodiment of the present invention, at least one of the circulation openings positioned downstream of the narrowest point of the diffuser passage is arranged within the diffuser passage between the pressure side of a diffuser vane and the suction side of an adjacent diffuser vane.
According to one embodiment of the present invention, at least one of the circulation openings positioned downstream of the narrowest point of the diffuser passage is positioned behind the outlet of the diffuser passage, wherein the outlet of the diffuser passage is determined by the vane outlet radius circle.
According to one embodiment of the present invention, at least one of the circulation openings positioned downstream of the narrowest point of the diffuser passage is arranged within the diffuser passage between the pressure side of a diffuser vane and the suction side of an adjacent diffuser vane and at least one further of the circulation openings arranged downstream of the narrowest point of the diffuser passage is positioned behind the outlet of the diffuser passage, wherein the outlet of the diffuser passage is determined by the vane outlet radius circle.
According to one embodiment of the present invention, each diffuser passage which has circulation openings is assigned a separate diffuser cavity.
According to one embodiment of the present invention, several or all of the diffuser passages which have circulation openings are assigned a joint diffuser cavity.
According to one embodiment of the present invention, the joint diffuser cavity is an annular channel.
According to one embodiment of the present invention, one or more diffuser cavities are connected to a secondary fluid source.
According to one embodiment of the present invention, the circulation openings assigned to a diffuser passage are positioned in each case upstream of the narrowest point of the diffuser passage.
According to one embodiment of the present invention, a diffuser passage is assigned circulation openings with different cross-sectional surface areas and/or cross-sectional forms and/or orientations.
According to one embodiment of the present invention, the number and/or the arrangement and/or the cross-sectional surface areas of the circulation openings vary in the circumferential direction of the diffuser vane ring.
According to one embodiment of the present invention, a radial compressor is equipped with a diffuser according to the invention, a compressor wheel which is arranged upstream of the diffuser and has compressor wheel vanes and a spiral housing arranged downstream of the diffuser.
According to one embodiment of the present invention, a turbocharger is fitted with a radial compressor which has a diffuser according to the invention.
The invention is described below on the basis of exemplary embodiments which are explained in greater detail on the basis of drawings. In the drawings:
Identical reference numbers are used for identical parts and parts with the same action in the following description.
The represented radial compressor comprises a compressor wheel 18 which is arranged on a shaft 17 and which comprises a hub 19 and compressor wheel vanes 20 arranged on this hub. This compressor wheel is arranged in a compressor housing which generally comprises several components. These include a spiral housing 21 and an inlet housing 22. A bearing housing 24, in which shaft 17 is mounted, is located between the compressor and the turbine, not represented in
Diffuser 2 which has a flow channel 3 and which serves to slow down the flow accelerated by the compressor wheel is arranged downstream of the compressor wheel in the direction of flow of the medium to be compressed. This is performed on one hand by diffuser vanes 6 of a diffuser vane ring, on the other hand by spiral housing 21 which has a spiral housing tongue in the transition region to flow channel 3 of diffuser 2. The compressed medium is supplied from the spiral housing to the combustion chambers of an internal combustion engine. Diffuser vanes 6 are connected on one side or both sides of flow channel 3 to a first side wall 4 or a second side wall 5.
Moreover, a pressure-equalizing opening, not represented in
The diffuser vanes shown in
One alternative embodiment lies in assigning each diffuser passage an individual diffuser cavity which is connected via a respective pressure-equalizing opening 11 to the respective diffuser passage.
Another alternative embodiment lies in not forming pressure-equalizing openings 11 in a slot-shaped manner, but rather to be circular.
In contrast to the embodiments described on the basis of
As a result of the positioning of the several circulation openings assigned to a diffusor passage, a connection of a position arranged downstream to a position arranged upstream, preferably a connection of a position arranged downstream of the narrowest point of the respective diffuser channel to a position arranged upstream of the narrowest point of the respective diffuser passage is performed via the diffuser cavity. As a result of such a positioning of the circulation openings assigned to a diffuser passage, it is achieved that a discharge of the supplied fluid into the diffuser cavity is performed by way of the circulation opening arranged in each case downstream and a return of fluid from the diffuser cavity into the diffuser passage is performed by way of the circulation opening arranged in each case upstream, which locally reduces the flow cross-section aerodynamically and influences the direction of flow and speed. If this arrangement is embodied on the shroud side, i.e. on the side of the diffuser facing away from the bearing housing, an aerodynamic expansion of the diffuser vane extending in the upstream direction can thus be achieved by corresponding positioning of the circulation openings. In the case of such a positioning of the circulation openings, an existing pressure difference is respectively used to drive a fluid mass flow through the diffuser cavity.
As a result of these measures, it is advantageously achieved that the mass flow rate conducted past the diffuser passage and the returned mass flow rate bring about automatic regulation according to a desired rotational speed characteristic curve of the compressor arranged upstream of the diffuser. This leads to a stabilization of the compressor operation. As a result of the return of the fluid, the surge limit of the compressor is advantageously displaced in the direction of lower fluid mass flow rates and, as a result of the discharge of the fluid, the choke limit of the compressor is displaced in the direction of higher fluid mass flow rates. This corresponds to an increase in size of the working range of the compressor. In this case, a deceleration or even a disappearance of the fluid flow can arise in the range between the surge limit and the choke limit, which has advantages in terms of the maximum efficiency which can be achieved.
In order to further increase the advantages described above of the invention, the number of circulation openings assigned to the respective diffuser passage can be increased. This increases in particular the stabilization effect of the described measures. This is in particular due to the fact that the measures described at least delay an occurrence of critical fluid flow situations on the shroud side and/or the stroke side of the diffuser and as a result expand the working range of the compressor.
The circulation openings of the diffuser passages can all have the same cross-sectional form and the same cross-sectional surface area. Alternatively to this, it is also possible that the circulation openings assigned to a diffuser passage have different cross-sectional forms and/or cross-sectional surface areas and/or different orientations.
These circulation openings and their relative positioning to one another must in any event be configured so that the fluid flow flowing through the circulation openings is sufficiently large in order to increase the working range of the diffuser in comparison with the working range of known diffusers.
For example, one embodiment lies in selecting the spacing of circulation openings spaced apart from one another in the direction of flow so that it is at least 25%, preferably at least 30% or at least 35% of the chord length of a diffuser vane.
Another embodiment lies in selecting the spacing of circulation openings adjacent to one another perpendicular to the direction of flow so that it is at least 25% of the spacing between two diffuser vanes adjacent to one another.
A further embodiment lies in the fact that, at at least one operating point, the percentage ratio of the mass flow which circulates through the circulation openings is greater than 1% of the entire mass flow.
Sketches to illustrate possible arrangements of the circulation openings assigned to a diffuser passage are explained in greater detail below on the basis of
Both circulation openings 11 are fluidically connected to one another by a diffuser cavity formed as an annular channel and common to all the diffuser passages. This annular channel extends around the entire circumferential region of the diffuser vane ring and consequently connects diffuser passages 131 to 1318 fluidically to one another via circulation openings 11 of these diffuser passages.
An advantageous further development of the invention which can be used in all the exemplary embodiments described above lies in connecting a joint diffuser cavity formed as an annular channel to a secondary fluid source. The fluid provided by this secondary fluid source can be used to rinse the annular channel with the fluid where necessary. As a result, potential deposits and residues from carbonization by oil-containing intake air which could block the annular channel and the circulation openings can be rinsed out of the annular channel and thus also out of the circulation openings.
One alternative embodiment of the invention lies in only assigning certain diffuser passages with circulation openings, for example, those diffuser passages which are arranged in a circumferential region of the diffuser vane ring, in the vicinity of which instabilities can arise during operation, for example, in the vicinity of a spiral tongue-side outlet of the flow channel of the diffuser.
One advantageous embodiment of the invention lies in providing the diffuser cavity/cavities and the circulation openings in the shroud-side side wall of the diffuser.
A further advantageous embodiment of the invention lies in embodying the side walls of the diffuser to be divergent at least in portions.
A further advantageous embodiment of the invention lies in using diffuser vanes with different profiles.
A further advantageous embodiment of the invention lies in varying the input angles of the diffuser passages by rotating diffuser vanes.
A further embodiment of the invention lies in assigning each diffuser passage which has circulation openings a separate diffuser cavity. This diffuser cavity can be a simple connecting line.
A further embodiment lies in fluidically connecting a circulation opening assigned to a diffuser passage to a circulation opening assigned to a different diffuser passage, preferably to a circulation opening assigned to an adjacent diffuser passage, via the diffuser cavity, for example, a circulation opening arranged upstream of the narrowest point of a diffuser passage to a circulation opening assigned to a directly adjacent diffuser passage downstream of the narrowest point.
Number | Date | Country | Kind |
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10 2017 118 950.5 | Aug 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/072247 | 8/16/2018 | WO | 00 |