Exhaust gas turbine of a turbocharger for an internal combustion engine

Information

  • Patent Grant
  • 6314736
  • Patent Number
    6,314,736
  • Date Filed
    Wednesday, April 26, 2000
    24 years ago
  • Date Issued
    Tuesday, November 13, 2001
    23 years ago
Abstract
An exhaust gas turbine portion of a vehicle engine turbocharger is provided with at least one variable guide-blade cascade with guide blades in a nozzle opening to the turbocharger rotor for effectively changing the cross section of the exhaust flow to the rotor wherein the angle of the guide blades is selectively settable by an adjusting device. The width dimension of the gap between the ends of the guide-blade cascade and the casing wall defining the nozzle is adjustable between a substantially zero gap dimension and a maximum gap dimension.
Description




CROSS REFERENCE TO RELATED APPLICATIONS




Priority is claimed under 35 U.S.C. 119 with respect to German Patent Application 199 61 613.2-13 filed on Dec. 21, 1999.




BACKGROUND OF THE INVENTION




1. Field of the Invention




The invention relates to an exhaust gas turbocharger for an internal combustion engine and specifically to the turbine portion having variably adjustable blades.




2. Description of Related Art




A generic exhaust gas turbine for a turbocharger is disclosed in DE 195 43 190 C2 which shows adjustable stop bodies in an annular nozzle arrangement to provide a variable adjustable blade arrangement. The stop bodies are utilized to increase the operating reliability of the exhaust gas turbine particularly in an engine braking mode of operation.




In addition, DE 198 38 928 C1 discloses in an exhaust gas turbocharger a turbine portion having a variably adjustable series of guide-blades. For each guide-blade, a sealing element is provided and located in a pressurized space. The sealing element design is in the form of sealing cups adapted to be sealingly pressed onto the free end of a blade so that the series gap formed at the end of the blade is completely sealed off. A disadvantage of this, however, is that a large number of sealing elements is required, one for each blade, and this increases expense and the susceptibility to operating faults. Furthermore, during adjustment of the blade and sealing member high adjusting forces have to be exerted to overcome frictional forces generated by pressing the sealing element onto the blade. Moreover, there is the risk of damage caused by a complete elimination of the end gap which allows an undesirably high rotational speed of the turbocharger particularly in an engine braking mode from relatively high engine speeds. Another problem with this seal design may occur by an undesirably great thermal expansion of an associated blade.




Another device is shown in JP 001 130002 AA which discloses an adjustable series of blades in which a precisely defined sealing gap is set by means of a spacer member.




SUMMARY OF THE INVENTION




The present invention utilizes a variably adjustable exhaust gas turbine whose efficiency is achieved by blade adjustment as a function of the operating state of the internal combustion engine. In particular, the subject device provides an improvement in acceleration behavior of the turbine particularly during an engine-braking mode of operation and in driving modes, even at low engine rotational speeds. It provides a rapid build-up of the engine inlet pressure developed by the turbocharger and therefore a corresponding rapid build-up of braking or driving torque. Accordingly, any overload of the exhaust gas turbine or of entire exhaust gas turbocharger under extreme conditions is avoided.




This object is achieved, according to the invention, by means of apparatus and by a regulating process as described hereinafter. Specifically, the exhaust gas turbocharger can always be optimally adapted or set-up relative to a desirable operating state of the internal combustion engine by controlling the axial gap between a maximum allowable gap and substantially a zero gap. Thus, for example, after a an initial adjustment of the series of blades, the axial end gaps can be advantageously reduced between the maximum to near zero by a clamping action. Resultantly, acceleration is improved even at a low engine rotational speed and following an engine-braking mode of operation. At the same time, by reducing end gap losses, a more rapid build-up of the inlet charge pressure to the engine and consequently a rapid build-up of braking torque can be achieved.




In an advantageous refinement of the invention, the guide blades can be clamped, for example by an annular piston, between a part of the casing wall which surrounds or forms the angular nozzle. This clamping inhibits excitations of the guide blades in the series of guide-blades.




Conversely, by increasing the axial gap in a controlled manner between zero and a maximum, the efficiency of the turbine portion can be readily controlled.




A particular advantageous feature of the gap varying or setting control of the gas turbocharger according to the invention is that the exhaust gas turbine can be operated close to its desired rotative speed so that the exhaust gas turbine has a correspondingly high efficiency. By a controlled increase in the axial gap between the blades and the housing, the effectiveness and speed of the turbocharger can be decreased particularly in an upper range of engine speeds. This inhibits damage to the exhaust gas turbine or to the exhaust gas turbocharger by the corresponding lowering of efficiency.











BRIEF DESCRIPTION OF THE DRAWINGS




Advantageous refinements and developments of the invention may be gathered from the exemplary embodiment described hereinafter with reference to the drawing, in which:





FIG. 1

is a diagrammatical illustration of an exhaust gas turbocharger with the exhaust gas turbine portion regulated according to the invention; and





FIG. 2

is a cross-sectional view taken through the turbine portion showing a first design of an annular control piston; and





FIG. 3

is an enlarged detail view of a second piston design; and





FIG. 4

is an enlarged detail view of a third piston design; and





FIG. 5

is an enlarged detail view of a fourth piston design.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




The general design and operation of an exhaust gas turbocharger is generally known and therefore its basic configuration is not discussed in great detail. A first exemplary embodiment of the invention is described with reference to

FIGS. 1 and 2

in which an exhaust gas turbine portion


1


of a turbocharger is shown. The turbine portion


1


is arranged in the exhaust gas stream discharged by an associated internal combustion engine


4


. The turbocharger includes a drive shaft


2


connecting turbine portion


1


to a compressor portion


3


of the turbocharger. The compressor portion


3


is arranged in an air intake flow or line


5


for feeding compressed air to the engine


4


.




The turbine portion


1


is in an exhaust gas flow line


6


extending from engine


4


. As best seen in

FIG. 2

, the gas turbine portion


1


has a surrounding spiral flow duct


7


operating to direct exhaust gas from inlet duct


7


through an annular opening or nozzle


8


to a turbine wheel or rotor


9


which is attached to the drive shaft


2


. A common enclosure housing or casing


10


supports and envelopes the turbine wheel or rotor


9


and forms the inlet flow duct


7


and the annular nozzle opening


8


. Specifically, the annular nozzle opening


8


is defined between axially spaced walls of the casing


10


.




A guide blade cascade or series


11


is located in the nozzle opening


8


and includes a multiplicity of individual guide blades


12


. The angular positioning relative to the flow of exhaust gas through the nozzle


8


of the guide blades


12


is adjustable by a guide blade adjusting device


13


so that the effective cross-sectional flow area of the nozzle opening can be selectively adjusted or set between a maximum opened operative position and a substantially closed operative position.




In

FIG. 2

, an annular piston


14


is shown supported by the casing


10


adjacent the leftward ends of guide blades cascade


11


. The rightward end of the annular piston


14


acts as a wall adjacent the end portions of the guide blades


12


. A pressure space


15


is defined at an opposite end portion of the annular piston


14


which faces away from the guide blades


12


. Pressure space


15


is connected via a pressure connection


16


to a pressurized feedline


17


. In a preferred form, where possible, the pressure medium used for pressure space


15


is an on-board compressed-air network. Otherwise it is possible to provide for this pressurization by a specific pressure system including a pressure accumulator


18


as seen in FIG.


1


.




In order to achieve a great braking power, particularly in an engine braking mode and even at low engine speeds, the axial gap between the leftward end of the guide blades


12


and the adjacent rightward end wall of the annular piston


14


needs to be minimized or preferably eliminated. However, complete elimination of the axial gap has hitherto not been readily possible in the prior art because of thermal expansion of the guide blades


12


and the angle-setting adjusting or actuation device


13


used for the guide blades. In the subject arrangement, By means of the annular piston


14


which forms the axial wall defining blade movement or adjustment travel of the blades


12


, the axial gap between the ends of the guide blades


12


and the adjacent piston end or wall can be desirably established at various settings.




The regulation or setting of the extent of the axial gap is accomplished as follows: a force on the annular piston


14


for adjusting its position relative to the end so the blades


12


is developed from the fluid pressure of feedline


17


and the pressure accumulator


18


. Alternately, the pressure could be from the on-board compressed-air network. Appropriate desired pressure changes or pressure modulations are achieved by a pressure-regulating or shut-off device


19


which is activated by an engine control device


21


via control line


20


.




Alternatively, a control pressure may be generated via a branch line


22


connected as shown by broken lines in

FIG. 2

to the pressure connection


16






via a 3-way valve


31


.




The pressure accumulator


18


shown in

FIG. 1

may be charged by exhaust gas pressure from exhaust gas line


6


via a non-return valve


23


. Charging action may also be applied to the pressure accumulator


18


and thus to the pressure space


15


via an engine compressor


24


shown in FIG.


1


.




The gap setting is carried out under control of the setting of the regulating device


19


. Axial gap sizes and the level of the force pressing the end of the annular piston


14


onto the end of the guide blades


12


are implemented by pressure modulation via regulating device


19


. If required, the annular piston


14


may also be designed with a spring


25


which is preferably arranged in the pressure space


15


and thus would ensure a neutral position or an initial gap.




Two examples of an alternate application of the regulating process for varying the axial gap at the ends of the blades are described below.




1. Exhaust Gas Turbocharger Acceleration:




Starting from an operative condition in which blades


12


are closely engaged by the end of the annular piston


14


caused by the clamping force exerted by the fluid force created by pressure in space


15


which acts on the leftward end of the piston


14


, the axial gap is substantially eliminated. Then, the next step involves decreasing the force of piston


14


against the ends of the blades


12


by ventilation of the pressure-regulating valve


19


which decreases the pressure in space


15


. Then the angle of the guide blades


12


can be set by means of the adjusting device


13


. Next, the pressure-setting valve


19


is activated to apply pressure from accumulator


18


to the space


15


which creates a force on piston


14


to move it rightward and closely against the end of the blades


12


. This results in a substantially zero-gap spacing between the end of piston


14


and the ends of the blades


12


.




If desired, a timed pressure control cycle (bleed/load) may also be used, during the adjusting movement of the cascade


11


of blades


12


, using the adjusting device


13


, in order to obtain the smallest possible gaps laterally or axially.




2. Engine-Braking Via Turbo-Braking:




In a first step, the above described clamping force of the annular piston


14


against the ends of the blades


12


is relieved by decreasing pressure in space


15


by ventilation of the pressure-regulating device


19


. At relatively low engine rotation or speed, the angle of the guide-blades


12


is set via the guide-blade cascade adjusting device


13


, dependent on a corresponding engine speed. Then a substantially zero-gap setting is subsequently established by directing control pressure to the pressure chamber or space


15


. As with the first example, a timed pressure/ventilation sequence of pressure application or control can be utilized during the interim for adjusting the angle of the blades


12


by the adjusting device


13


. Thus, the gap can be maintained desirably small. Eventually when the engine tends to exceed a set upper limit of rotational speed, the axial gap can be increased to limit the speed by decreasing the pressure in the pressure space


15


. This produces a controlled lowering of turbocharger efficiency and therefore inhibits damage to the turbine portion.




The annular piston


14


may be designed to exhibit a degree of elastically, at least at its rightward end facing in order to ensure that the annular piston effectively engages the ends of the blades


12


. This can be by providing the ends of the blades


12


with an elastic coating


27


. In addition, at least one piston ring


28


is utilized to provide a seal between the pressure gas space


15


and the annular nozzle


8


. This piston ring


28


may, in this case, be arranged in a groove in the casing


10


or in a groove in the annular piston


14


itself. For the sake of clarity, both possibilities are depicted as alternatives in

FIGS. 2

to


5


.




As seen in

FIG. 2

, the leftward end of each of the guide blades


12


may have a pin


29


extending into a bore


30


in the piston


14


. This allows the bore


30


to act as a bearing for the pin


29


as the blade


12


is rotated during setting of the blade's angle. This provides support for the leftward end portion of the blade


12


so that it is supported at both ends. This tends to increase stability and decrease vibration.




At least one axially directed pin


26


may be provided between the annular piston


14


and the support structure. Specifically, the pin


26


extends into bores in the support structure to the left of the annular piston


14


. Pin(s)


26


inhibit tilting of the annular piston


14


which would be a disadvantage in view of the support of the ends of blades


12


via the pin bearings


29


.




In principle, the further exemplary embodiments described below with reference to

FIGS. 3

,


4


and


5


function in substantially the same manner as the exemplary embodiment explained above. Therefore, the same reference symbols have been retained for the same parts and only the modifications are explained in detail.




According to

FIG. 3

, the annular piston


14


is configured as a thin-walled member, particularly in the middle region. Also, it does not have provision to interact with guide pins


26


as in the

FIG. 2

embodiment. In this case, the annular piston


14


does not serve as a secondary bearing support for the leftward end of a guide blade


11


. This design is most useful for turbochargers having a lower exhaust gas force acting on the blades


12


. An angle adjusting or tilting of the blades


12


may, in this case, be neutralized by a clamping action of the annular piston


14


bearing against the leftward ends of the blades


12


.




As is apparent in

FIG. 3

, the annular piston


14


is tapered very sharply or is much thinner particularly across its middle or central region so that it bears elastically against the ends of the blades


12


under the effect of high pressure forces acting on the piston


14


from pressure space


15


. Thereby, the piston


14


securely clamps the guide blades in their respective set angular positions. In this particular embodiment, annular piston


14


may likewise be actuated by compressed-air via a connection


16


under control of three-way valve


31


as disclosed in FIG.


2


.




In

FIG. 4

, a further refinement of annular piston


14


is disclosed and a damping device or arrangement is shown. Specifically, a damping ring member


33


lies mostly within a recess formed by the central portion of annular piston


14


and is sealed via piston rings


32


. As previously described, alternate support of piston ring


32


is shown first in an annular groove formed in the damping ring member


33


(upper illustration) and second in an annular groove of the annular piston


14


(lower illustration). The annular piston


14


and damping ring


33


are separated or pressed apart from one another by a spring


34


. The interspace


35


between the annular piston


14


and the damping ring


33


is filled with compressed air from pressure space


15


via one or more throttle bores


36


.




The damping effect of annular piston


14


is achieved in the following way: if there are pulsations of the exhaust gas flowing through the turbine portion, the annular piston


14


is capable of executing only an inhibited or delayed movement in an axial direction in relation to the turbine. Vibrations are inhibited by a slow escape of pressure from interspace


35


through the throttle bores


36


since the bores


35


have only a small diameter.




The embodiment or version illustrated in

FIG. 5

also supports both ends of the blades


12


as in the first embodiment. In contrast to the support arrangement illustrated in

FIG. 2

, each pin or bearing pins


29


in this embodiment is not supported by the annular piston


14


but instead is supported by the portion of the stationary turbine casing


10


located behind the piston


14


. Specifically, an oversized bore


38


is formed through the piston


14


and particularly in a radially outwardly projecting extending portion


37


of the piston


14


. The bearing pin


29


extends through the bore


38


and into a bearing bore


39


formed in the casing


10


.




An advantage of this type of mounting or support is that the bearing pins


29


can be press mounted in the bore


39


as a fixed shaft supported by the casing


10


. Accordingly, the guide pins


26


affixed to the blades


12


, as illustrated in

FIG. 2

, can be dispensed with. At the same time, the support of the blades at both ends improves the above described braking operation since the annular piston


14


is not subjected to great forces but the blades


12


are well supported. In this embodiment, as in

FIG. 4

, both alternate mounting arrangements for piston ring


28


is shown.



Claims
  • 1. In an turbocharger for an internal combustion engine having a housing defining an exhaust gas turbine portion including a rotor and defining a surrounding exhaust flow inlet duct with an annular nozzle opening therefrom to the rotor for directing exhaust gas flow to the rotor and having a guide-blade cascade of guide blades with their angular orientation relative to the flow direction through the nozzle opening being selectively settable by means of a guide-blade adjusting device for varying the effective flow cross-section of the nozzle opening, characterized by a gap setting device (14, 15, 16, 17) for selectively changing dimension of the gap at the ends of the guide-blade cascade (11) and the casing (10) between a substantially zero gap dimension and a maximum gap dimension.
  • 2. The exhaust gas turbine portion as set forth in claim 1 in which an annular piston (14) is reciprocally supported by the casing wall adjacent the end portion of the guide-blade cascade (11), the casing (10) and the annular piston (14) defining a pressure space (15) to which fluid pressure can be selectively directed for controlling movement of the annular piston (14) relative to the end portions of the guide blades (12) of the guide-blade cascade (11).
  • 3. The exhaust gas turbine portion as set forth in claim 2 and with a spring (25) urging the annular piston (14) toward the end portion of the guide-blade cascade (11).
  • 4. The exhaust gas turbine portion as set forth in claim 2 including pins (26) provided to guide and center the annular piston (14).
  • 5. The exhaust gas turbine portion as set forth in claim 2 and the annular piston (14) having an elastic coated end (27) facing the end portions of the guide-blades cascade (11).
  • 6. The exhaust gas turbine potion as set forth in claim 2 in which the pressure space (15) partially defined by the annular piston (14) is selectively connected to a pressure-regulating device (19).
  • 7. The exhaust gas turbine portion as set forth in claim 6 in which the pressure-regulating device (19) is connected to an engine control device (21) by a control line (20) for modulation of pressure in the pressure space in accord with engine operation.
  • 8. The exhaust gas turbine portion as set forth in one of claims 2, 6, and 7 including a three-way valve (19) for alternately controlling pressurization of the pressure space (15) and having two pressure activation lines (17, 22) provided for the pressure space (15) and a stop position.
  • 9. The exhaust gas turbine portion as set forth in claim 8 in which one of the two pressure activation lines is connected to a source of fluid pressure (18) which generates a substantial pressure, and the other of the two pressure activation lines is connected to the flow duct (7) wherein the pressure of the source of fluid pressure (18) is higher than the pressure from the flow duct (7).
  • 10. In an turbocharger for an internal combustion engine having a housing defining an exhaust gas turbine portion including a rotor and defining a surrounding exhaust flow inlet duct with an annular nozzle opening therefrom to the rotor for directing exhaust gas flow to the rotor and having a guide-blade cascade of guide blades with their angular orientation relative to the flow direction through the nozzle opening being selectively settable by means of a guide-blade adjusting device for varying the effective flow cross-section of the nozzle opening, characterized by a gap setting device (14, 15, 16, 17) for selectively changing dimension of the gap at the ends of the guide-blade cascade (11) and the casing (10) between a substantially zero gap dimension and a maximum gap dimension.
  • 11. The exhaust gas turbine portion as set forth in claim 10 in which an annular piston (14) is reciprocally supported by the casing wall adjacent the end portion of the guide-blade cascade (11), the casing (10) and the annular piston (14) defining a pressure space (15) to which fluid pressure can be selectively directed for controlling movement of the annular piston (14) relative to the end portions of the guide blades (12) of the guide-blade cascade (11).
  • 12. The exhaust gas turbine portion as set forth in claim 11 in which the annular piston (14) has a central thin-walled configuration.
  • 13. The exhaust gas turbine portion as set forth in claim 11 and including at least one pin bearing (29) mounted in a bore (30) formed in the annular piston (14) and engaging the end of the guide blades (12) away from the guide-blade cascade adjusting device (13).
  • 14. The exhaust gas turbine portion as set forth in claim 12 and including at least one pin bearings (29) extending through bores (38) in an extension ring portion (37) of the annular piston (14) and inserted in bearing bores (39) in the casing (10) away from the guide-blade cascade adjusting device (13).
  • 15. The exhaust gas turbine portion as set forth in claim 11 in which a damping ring (33) is supported within the annular piston (14) between it and the casing (10) and a spring (34) urges the annular piston (14) and damping ring (33) apart from one another, an interspace (35) is defined between the annular piston (14)and the damping ring (33) with at least one throttle bore (36)connecting the piston space (15) and the interspace (35).
  • 16. A regulatory system for an exhaust gas turbine portion of an exhaust gas turbocharger for an internal combustion engine including a rotor and having a casing defining a surrounding exhaust flow inlet duct with an annular nozzle opening therefrom to the rotor for directing exhaust gas flow to the rotor and having a guide-blade cascade of guide blades with their angular orientation relative to the flow direction through the nozzle opening being selectively settable by means of a guide-blade cascade adjusting device for varying the effective flow cross-section of the nozzle opening, characterized in that a gap setting device (14, 15) is controlled by a pressure regulating device (19) for selectively providing a gap dimension between the gap setting device (14) and the ends of the guide-blade cascade (11) between a substantially zero dimension gap and a maximum dimension gap.
  • 17. A turbocharger for an internal combustion engine having a housing defining an exhaust gas turbine portion including a rotor and defining a surrounding exhaust flow inlet duct with an annular nozzle opening leading from said inlet duct to the rotor for directing exhaust gas flow to the rotor, and a guide-blade structure disposed in said nozzle opening and having guide blades whose angular orientation relative to the flow direction through the nozzle opening is selectively settable by means of a guide-blade adjusting device connected to one axial end of said guide blade structure for varying the effective flow cross-section of the nozzle opening, a gap setting device disposed adjacent the other axial end of said guide blade structure for selectively changing the dimension of the axial gap between the other axial end of the guide-blade structure and the housing between a substantially zero gap dimension and a maximum gap dimension, said gap setting device including an annular piston reciprocally supported in the wall of said housing adjacent the other axial end of the guide-blade structure, said annular piston defining at its end opposite said guide blades a pressure space to which fluid under pressure can be selectively directed for controlling axial movement of the annular piston relative to the axial end of the guide blades of the guide-blade structure for adjusting any gap between the annular piston and the guide-blade structure.
  • 18. A turbocharger according to claim 17, further comprising a spring urging said annular piston toward said guide blade structure.
  • 19. A turbocharger according to claim 17, wherein pins are provided between said housing and said annular piston for guiding and centering said annular piston.
  • 20. A turbocharger according to claim 17, wherein said annular piston has an elastic coated end facing said guide blade structure.
  • 21. A turbocharger according to claim 17, wherein said pressure space, which is partially defined by said annular piston, is connected to a pressure supply line which includes a pressure-regulating device.
  • 22. A turbocharger according to claim 17, wherein said pressure-regulating device is connected to an engine control device by a control line for controlling the pressure in the pressure space in accordance with engine operating conditions.
  • 23. A turbocharger according to claim 17, wherein a three-way valve is provided for alternatively controlling pressurization of said pressure space by way of a first and a second pressurization line for the pressure space.
  • 24. A turbocharger according to claim 23, wherein said first pressurization line is connected to a source of fluid pressure and said second pressurization line is connected to a flow duct, wherein the pressure of the source of fluid pressure is higher than the pressure in the flow duct.
Priority Claims (1)
Number Date Country Kind
199 61 613 Dec 1999 DE
US Referenced Citations (5)
Number Name Date Kind
5146752 Bruestle Sep 1992
5214920 Leavesley Jun 1993
5600956 Nytomt Feb 1997
5758500 Sumser et al. Jun 1998
5855117 Sumser et al. Jan 1999
Foreign Referenced Citations (3)
Number Date Country
195 43 190 C2 Nov 1995 DE
198 38 928 C1 Aug 1998 DE
0010130002 AA Nov 1987 JP
Non-Patent Literature Citations (1)
Entry
Article by A. Feuerstein and W. Bialojan entitled “Beschichten im Vakuum” dated Dec. 1992.