Abstract:
The motor-assisted variable geometry turbocharging system has a motor to add power to the turbocharger rotating assembly, especially at low exhaust gas volume. Additionally, the system includes a control over compressor air inlet direction, and/or control of exhaust gas to a two-volute expander. These are individually controlled, or controlled in combination, to enhance turbocharged engine performance. In a preferred embodiment, the system comprises an electric motor, mounted directly within the turbocharger main housing, variable pre-whirl vanes mounted upstream of the turbocharger compressor, and a diverter valve in the exhaust piping upstream of a divided turbine volute.

Description:
This is a division of U.S. patent application Ser. No. 08/811,474 filed Mar. 4, 1997, abandoned, which is a continuation in part of U.S. patent application Ser. No. 08/714,618 filed Sep. 16, 1996, abandoned, which is a continuation of U.S. patent application Ser. No. 08/508,442 filed Jul. 28, 1995, now U.S. Pat. No. 5,560,208. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates generally to variable geometry components used in turbochargers applied to internal combustion engines that operate over a broad range of speed and load. 
     BACKGROUND OF THE INVENTION 
     Fixed geometry turbochargers can be designed to operate efficiently at a particular engine load and speed. However, when operated over a broad range of engine speed and load, the compressor and turbine components are forced to function off their design points and, consequently, suffer losses in efficiency that affects engine performance adversely. If the turbocharger is matched to an engine at the engine&#39;s rated speed, it will run considerably off its maximum efficiency when the engine is “torqued down” to low engine operating speeds. Conversely, if the turbocharger is matched to an engine&#39;s low speed range, the turbocharger will have a tendency to “overspeed” when the engine is operated at maximum speed and load. 
     To prevent overspeeding in turbochargers that have been matched to the low engine speed range, a waste gate is frequently used to bypass exhaust gas around the turbine to limit turbine speed over the high engine speed range. The waste gate, however, allows the escape of exhaust gas energy, which could be better utilized by the turbocharger turbine, and results in a substantial loss in system efficiency. 
     A more efficient system generally known in the trade is one comprising variable geometry components in the turbocharger compressor, the turbocharger turbine, or both. The most common types are variable nozzle vanes ahead of the turbine wheel, and/or variable diffuser vanes in the compressor component. 
     Variable nozzle vanes ahead of the turbine wheel are connected together so that the throat area of each nozzle passage can be reduced over the low engine speed range and increased as the engine speed approaches its maximum, so that the turbocharger speed is kept within a safe operating range. The positioning of the vanes must be precisely controlled by engine speed and load, and they must be freely movable in the hot exhaust gas environment with minimal leakage through clearance spaces. 
     The various movable devices that have been employed in the turbocharger turbine have been complicated, expensive and subject to questionable durability. Consequently, they have met with limited commercial success. 
     A more practical approach to a variable device in the engine exhaust system was disclosed in U.S. Pat. No. 3,557,549 to Webster, assigned to Caterpillar Tractor Co., 1971. This system employs a flapper valve so positioned in a divided manifold system that it resides in a neutral position at high engine speed and load, but can be moved to a second position where it diverts all engine exhaust gas flow into one passage of a divided turbine casing at low engine speeds. This essentially doubles the flow of exhaust gas through the single turbine casing passage and maintains the turbocharger speed at higher levels than otherwise could be reached at low engine speeds. This device is much simpler than the complicated variable nozzle vane systems and does not require a precise control system for positioning. 
     The use of the flapper valve to divert exhaust gas allows the turbocharger to be matched efficiently to the higher engine speeds where the flapper is in a neutral position. When the engine is operated at low engine speeds, the diversion of full exhaust flow of the single turbine casing passage ahead of the turbine increases the turbocharger rotor speed to provide higher boost pressure to the engine cylinders, allowing the engine to produce more power and torque than otherwise could be obtained. 
     The increase in boost at low engine speeds produced by the diverted flapper valve might be great enough to cause the turbocharger compressor to operate in its surge or unstable area. In this case, the compressor must be rematched to move its surge line to lower airflow so that the engine operating points fall within its stable operating regime. However, this causes a movement of the compressor efficiency islands and choke area to lower flow and can result in lowering the compressor efficiency when the engine is operating at high speed and load. 
     A variable geometry compressor that can shift the performance map of the compressor to a lower or higher flow range is one solution to the problem of keeping the compressor out of surge at low engine speeds and still maintain high efficiency at high engine speeds. Variable diffuser vanes is one type of variable geometry compressor that could be employed, but the movable vanes cause significant mechanical complication internally in the construction of the turbocharger and must be precisely positioned by a rather elaborate control system. 
     A more practical type of variable geometry device is to employ movable pre-whirl vanes upstream of the compressor wheel to provide positive and negative pre-whirl to the air entering the inducer of the compressor wheel. Negative pre-whirl moves the compressor operating range to higher flow and usually improves compressor efficiency. Positive pre-whirl moves the compressor operating range to lower flow and usually lowers compressor efficiency somewhat. However, since the maximum island of compressor efficiency is also moved to lower flow, the net effect of positive pre-whirl is to raise the level of efficiency available to the operating area of the engine. 
     It is thus advantageous to connect the movable flapper valve in the exhaust stream to the movable pre-whirl vanes in the airstream by a mechanical linkage, causing them to move in synchronization. With the flapper in neutral, the pre-whirl vanes are positioned to provide negative pre-whirl to the compressor, moving its flow range, so that the maximum efficiency is available in the high engine speed range. When the flapper is in the diverted position, the pre-whirl vanes are moved to the positive pre-whirl position, thereby moving the maximum compressor efficiency to the low engine range. A simple, hydraulic cylinder or solenoid can be employed as an actuating means to move the mechanical linkage to either the high flow or low flow position by sensing the engine speed at which the transition is required to be made. 
     Both the flapper valve and the pre-whirl vanes are external from the turbocharger construction, resulting in much lower overall cost than other variable geometry devices that must be built into the internal construction of the turbocharger. 
     The movement of the compressor flow range by utilizing positive and negative pre-whirl is more fully described in a paper published in the  Proceedings of the Institute of Mechanical Engineers,  Vol. 18943/75, entitled “Experimental and Theoretical Performance of Radial Flow Turbocharger Compressor with Inlet Pre-Whirl”, by Wallace, Whitfield and Atkey. It is also described in U.S. Pat. No. 5,025,629 to Woollenweber, June 1991. 
     SUMMARY OF THE INVENTION 
     In order to aid in the understanding of this invention, it can be stated in essentially summary form that it is directed to a motor-assisted variable geometry turbocharging system. The variable geometry is provided by the exhaust gas flow control configuration into the exhaust gas turbine, and/or the air inlet flow control into the air compressor, together with a motor drive for the turbocharger rotating assembly to enhance performance of a turbocharged engine. 
     It is thus a purpose and advantage of this invention to provide a motor drive for the turbocharger rotating assembly to supply power into the turbocharger system, in addition to that which can be achieved by extracting power from the exhaust gas. 
     It is a further purpose and advantage of this invention to provide a motor for adding power to a turbocharger which also includes control of the air inlet to the turbo compressor by the use of pre-whirl vanes upstream of the compressor wheel to move the flow range of the compressor in coordination with the flow requirements of the engine. 
     It is a further purpose and advantage of this invention to supply external power to a turbocharger, which is driven by exhaust gas expansion, by including a motor to supply torque to aid in rotating the shaft in the air compressor direction, and to include such an assisting motor together with control of airflow into the turbo compressor to enhance engine performance. 
     It is a further purpose and advantage of this invention to provide a motor connected to a turbo compressor rotating assembly, and control the motor in addition to controlling exhaust gas flow to the turbine and/or airflow into the turbocharger compressor to enhance engine performance. 
     It is a further purpose and advantage of this invention to provide an electric motor, mounted within the turbocharger central housing, so that the above-described purposes and advantages can be attained with minimum space utilization and as an item of original equipment for the engine manufacturer. 
     The features of the present invention which are believed to be novel are set forth with particularity in the appended claims. The present invention, both as to its organization aid manner of operation, together with further objects and advantages thereof, may be best understood by reference to the following description, taken in conjunction with the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic view of a turbocharging system which has a motor to add power to the turbocharger rotor, and has control of exhaust gas flow into a two-volute turbo expander; 
     FIG. 2 is a schematic view of a turbocharging system which has a motor to add power to the turbocharger rotor, and has control of the airflow into the compressor; 
     FIG. 3 is a schematic view of a turbocharging system, wherein the turbocharger has a motor to add power to the rotor, has control of exhaust gas flow into a two-volute turbo expander, and has control of airflow into the compressor; 
     FIG. 4 is a schematic system similar to FIG. 3, but the exhaust gas flow into the turbo expander is controlled simultaneously with the control of airflow to the compressor. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     To improve engine and vehicle response to opening of the throttle, an external power source is needed to operate the turbocharger at higher speed at engine idle in order to provide increased boost levels in the engine intake system in preparation for quick acceleration. This can be an electric motor, a hydraulic motor, a pneumatic motor, or the like, particularly a motor which can have its power output controlled. A preferred example and the example given below of an external power source is an electric motor that engages the turbocharger rotor at engine idle and increases the idle speed of rotation of the rotating assembly. 
     Having higher boost pressure available at engine idle speed than the boost pressure the turbocharger can provide from exhaust gas energy alone, allows fuel to be injected into the engine cylinders sooner during acceleration and reduces smoke and emissions during the transient period. The engine is able to produce more output torque during transients, and the higher boost pressure during acceleration should eliminate the need for fuel limiting devices, such as an aneroid control or fuel pump rack limiters. 
     The electric motor, coupled to the turbocharger rotor, can be energized before the engine is stared. Then, during cranking of the engine, a positive differential pressure will exist across the engine from intake manifold to exhaust manifold. In the case of a two-cycle engine, a positive differential is necessary for scavenging the cylinder during cranking. Therefore, if a two-cycle engine is turbocharged with an electric motor assist, the need for a gear-driven blower to provide the scavenge differential pressure needed for starting is eliminated. 
     The motor-assisted variable geometry turbocharging system of this invention is generally indicated at  10  in FIG.  1 . Diesel engine  12  has two exhaust manifolds  14  and  16 , which are separately ducted to the two volutes  18  and  20  of exhaust gas turbine  22 . Valve  24  controls whether or not exhaust gas is delivered to one or both volutes. When exhaust gas volume is low, delivery of all exhaust gas to one volute provides a higher exhaust gas pressure, which delivers more power to the exhaust gas turbine rotor  26 . Valve  24  is controlled by valve controller  28 . 
     The exhaust gas turbine rotor  26  is mounted on turbocharger shaft  32  which, in turn, drives turbo compressor  34 . The turbo compressor has a compressor rotor  36  therein so that, when rotated, air is drawn into inlet  38  and is delivered through outlet  40  to the engine intake system. 
     This structure is generally seen in Woollenweber U.S. Pat. No. 5,025,629, the entire disclosure of which is incorporated herein by this reference, see FIG. 9 thereof. For the reasons discussed above, and in addition to the variable geometry discussed in that patent, there are problems in delivering enough combustion air to the engine  12 , particularly at low exhaust gas rates. For this reason, motor  42  is mounted to assist the turbocharger rotating assembly. The motor  42  may be an electric motor, a pneumatic motor, a hydraulic motor, or other type of motor. Preferably, however, motor  42  is an electric motor, with its rotor attached to the turbocharger rotating assembly, and its stator mounted in the interior of the turbocharger housing, with electric control line  45  supplying the appropriate motor control signals from motor control  44 . When the engine is operating at low speed and there is an engine demand for more power and more speed, the valve  24  is in the single-volute, diverted position, and the motor  42  is energized to add power to the turbocharger. As the exhaust gas volume goes up, the valve can be switched to the neutral, double-volute position and, when exhaust gas is fully adequate to supply the entire power demand of the turbo compressor, no power need be supplied to the motor  42 . If the motor  42  is configured so that it cannot be rotated as fast as the top speeds of the shaft  32 , the motor  42  can be de-energized via control line  45 . Thus, power is supplied to the motor  42  and the valve  24  is appropriately controlled for optimum turbocharger operating conditions under the engine speed and demand requirements. 
     FIG. 2 illustrates a similar turbocharging system  46  for a diesel engine. Turbocharging system  46  has an exhaust gas turbo expander rotor  50  mounted on turbocharger shaft  52 . Compressor rotor  54  is driven by the shaft  52  and is mounted in compressor housing  56 . Air is delivered from outlet  58  to the air inlet of the engine. Electric motor  60  is controlled by a motor controller  62  via line  63 . Inlet  66  of the turbocharger has adjustable vanes, such as at  67  therein, which provide pre-whirl to the air inlet stream. As discussed in the references above, this pre-whirl adjusts the compressor performance. The pre-whirl can be adjusted by appropriate movement of the vanes, which causes the pre-whirl to adjust compressor performance. The vane control  68  thus provides variable geometry in the turbo compressor. Both the vane control and the motor control are individually adjusted to provide optimum turbocharging performance under the particular engine operating parameters and performance demands. The adjustment of turbo compressor conditions by control of input pre-whirl is discussed in the above-referenced publication. 
     FIG. 3 shows a turbocharging system  70  similar to the system shown in FIGS. 1 and 2. The turbocharging system  70  has a dual volute exhaust gas expander with the diverter valve  71 , which diverts all exhaust gas flow from the split manifold of the engine to one volute for higher performance at low exhaust gas flow rates, as previously described. Furthermore, the compressor  72  has a pre-whirl control  74  at the air inlet to the compressor  72 . Additionally, motor  76  is directly connected to the turbocharger rotating assembly. 
     The pre-whirl vane control  78  and the motor control  80 , respectively, control the pre-whirl vanes in response to an engine speed signal, and the motor  76  is independently controlled to provide additional boost during engine acceleration. Diverter valve  71  is also controlled by valve control  83  in response to an engine speed signal so that all exhaust gas is diverted to one volute below a pre-determined engine speed. 
     FIG. 4 shows a system  84  which is structurally much like the system of FIG.  3 . Coordinated therewith, and cooperating therewith, controller  92  controls through line  93  both the vanes  94  which control the pre-whirl and, through line  96 , controls diverter valve  97 . Since the pre-whirl control also controls the diverter valve, the two functions are coordinated. The control of the motor  90  remains independent of the control of the pre-whirl vanes and the diverter valve and is controlled by motor control  88  through line  89 . 
     This invention has been described in its presently contemplated best modes, and it is clear that it is susceptible to numerous modifications, modes and embodiments within the ability of those skilled in the art and without the exercise of the inventive faculty. Accordingly, the scope of this invention is defined by the scope of the following claims.