The invention relates to a flow control device for a turbocharger.
Turbochargers for gasoline and diesel internal combustion engines are known devices used in the art for pressurising the intake air stream, routed to a combustion chamber of the engine, by using the heat and volumetric flow of exhaust gas exiting the engine. Specifically, the exhaust gas exiting the engine is routed into a turbine housing of a turbocharger in a manner that causes an exhaust gas-driven turbine to spin within the housing. The exhaust gas-driven turbine is mounted onto one end of a shaft that is common to a radial air compressor mounted onto an opposite end of the shaft. Thus, rotary action of the turbine also causes the air compressor to spin within a compressor housing of the turbocharger that is separate from the exhaust housing. The spinning action of the air compressor causes intake air to enter the compressor housing and be pressurised a desired amount before it is mixed with fuel and combusted within the engine combustion chamber.
The amount by which the intake air is pressurised is controlled by regulating the amount of exhaust gas that is passed through the turbine housing by a wastegate and/or by selectively opening or closing an exhaust gas channel or passage to the turbine running through the turbine housing. Turbochargers that are constructed having such adjustable exhaust gas channels are referred to in industry as variable geometry turbines (VGTs). VGTs typically include a movable member that is positioned within a turbine housing between the exhaust gas source and the turbine. The movable member is actuated from outside of the turbine housing by a suitable actuating mechanism to increase or decrease the volumetric flowrate of exhaust gas to the turbine as called for by the current engine operating conditions which may be, for example, engine speed, engine load, boost (compressor) pressure or differential pressure across the engine. Increasing or decreasing the volumetric flowrate of exhaust gas to the turbine respectively increases or decreases the intake air boost pressure generated by the compressor mounted on the opposite end of the turbine shaft.
One known VGT is described in U.S. Pat. No. 6,158,956.
VGTs can operate with the internal combustion engine when the latter is in either steady state or transient operating mode. This refers to engine operating parameters such as engine rotational speed and load being of constant or changing magnitude respectively.
Accordingly, conventional Variable Geometry Turbochargers (VGTs), on the other hand have become quite popular recently in matching turbine inlet geometry to the characteristics of the exhaust gas stream throughout the engine operating range beyond the selected optimum design point, according to which, fixed geometry turbochargers were designed in the first place. This has led (especially in combination with matched Exhaust Gas Recirculation systems) to a reduction in particle emissions, higher boost especially at the lower speeds, low load conditions, leading therefore to increased available torque and improved acceleration at the lower part of the engine operating envelope. In addition, turbocharger lag performance has improved dramatically.
The problem remains that although VGT's can alter turbocharger geometry according to engine operating conditions they do not take full advantage of the energy available. If more energy was recovered during each exhaust process period, this could raise the amount of energy absorbed by the turbine and therefore the turbocharger could extract more power under the same engine operating conditions.
The invention is set out in the claims. Because movement of the flow restrictor is controlled dependent upon instantaneous engine conditions, improved energy extraction is obtained. Furthermore by provision of a pivoting linkage between a reciprocating actuator and a flow restrictor, fast restrictor response is provided.
In particular, the invention takes into account the pulsating nature of the exhaust gas stream rather than responding to operating point changes only as known in existing VGTs. The operation of such an engine's exhaust valves is such that during the exhaust process large amplitudes of gas mass flow and pressure are observed starting from low values when the valves start to open reaching a peak before the first half of the valve open period with the gas flow dissipating to approximately the same conditions as at the start of the process. This highly pulsating flow is driven directly to the turbine through an exhaust manifold and the turbine housing. The invention adapts turbine geometry at a frequency equivalent to the frequency of the engine exhaust pulses, to ensure that for any given engine condition, the maximum available constant turbine inlet pressure is achieved. As a result the real inlet conditions to the turbo charger including a highly pulsating flow field with a widely varying pressure and mass flow rate level are effectively harnessed.
The ACT provides a more accurate response to a real internal combustion engine, accommodating the periodic nature of its operation with air charge intake and compression, combustion, expansion and exhaust.
Embodiments of the invention will now be described, by way of example, with reference to the drawings, of which:
a is an exploded view of an active control turbo charger component;
b is a sectional side view of the component;
a shows displacement of a VGT flow restrictor (% open throat area) according to engine conditions (Engine speed Neng);
b shows the additional flow restrictor displacement (% open throat area) according to the invention for a given engine condition, against crank angle (CA);
c is a histogram of exhaust gas pressure as a function of crank angle,
a is a perspective view of a pivoting vane,
b is a side view of the pivoting vane in
a shows the relative positioning of adjacent vanes at position A in
b shows the relative positioning of adjacent vanes at position B in
b shows the relative positioning of adjacent vanes at point C in
b shows the relative positioning of adjacent vanes at point D in
a shows a pivoting vane ring in situ with a mixed flow rotor,
b shows a side perspective view of adjacent vanes at point E in
c shows an upper perspective view of adjacent vanes at point E in
In overview the invention provides a movable lightweight flow restricting member is disposed within a turbine housing, between a primary exhaust gas source and the turbine blades. The flow restricting member is axially disposable within the turbine housing. It is attached to a pivoting yoke which in turn attaches to a suitable actuator. Sensors are provided to monitor mass flow rate and pressure levels at the inlet, and to measure the axial position of the flow restricting member. This information is routed to a controller which undertakes to phase nozzle motion in the axial direction with the frequency and amplitude of exhaust pressure levels. As a result there is provided a system and method for providing active control of the pulsating exhaust gas flow at the inlet of a turbocharger turbine for use in internal combustion engines, and in particular taking into account the effect of opening and closing of the engine exhaust valves.
Referring to
At any instant, a rear portion of the flow restricting member (102) which is not protruding into the volute (104) is constrained to move between inner and outer cylindrical concentric fixed guides. The outer guide (106) fits around the outside diameter of the flow restricting member (102) with minimum clearance. The inner guide (108) has the same diameter as the inside of the flow restricting member (102) and fits tightly inside it to provide a bearing surface on which the flow restricting member (102) can slide. The inner guide (108) attaches to the wall of the turbine volute (104) and is responsible for holding the entire assembly together.
Towards its outward end, away from the volute (104), the flow restricting member (102) has 1st and 2nd diametrically opposing outward projections (116) which allow attachment to the receiving arms (121a, 121b) of a yoke (114). The projections (116) fit between the flow restricting member (102) and the yoke (114) and are pivotable to assist in translating the pivoting action of the yoke (114) into a reciprocating linear motion by the flow restricting member (102).
The yoke (114) includes a mounting arm (123) depending downwardly from the semi-circular receiving arms 121a, 121b and pivots about a pivot pin (118) at a point in the region of the junction of the mounting arm and the receiving arm. Below the pivot point the mounting arm (123) extends as a single tapered lever. The mounting arm (123) of the yoke (114) is slightly shorter than the upper semi-circular part to provide a ratio allowing less actuator displacement for any required linear displacement of the flow restricting member (102).
As can be seen from
Referring now to
To operate the apparatus effectively, an electronic control system is provided as shown in
The principle of active flow control is depicted in
c shows the variation of mass flow rate (m) and exhaust gas pressure (Ps) for three cylinders over a drive cycle. The figure displays that within one exhaust valve pulse, the gas pressure at the start of the pulse is approximately equal to that at the end of the pulse, and peaks there between. To track this, the movement of the flow restricting member therefore follows a sinusoidal control input and is itself sinusoidal as a result. Engine operating conditions determine the length of the exhaust valve pulse period and required inlet pressure. Therefore the ECU uses engine operating conditions to determine the amplitude and frequency of the sinusoid being followed at any instant, and to phase it with the exhaust valve pulses. It will be appreciated that any pressure variable, for example caused by any number of cylinder and timing schemes, can be accommodated by the control strategy.
a depicts the displacement of a VGT flow restrictor according to driving conditions. The individual lines depict constant air/fuel ratio (AFR) while each graph corresponds to one compressor exit or engine inlet manifold (boost) pressure, which itself is a measure of engine load. As can be seen, for a given AFR the open throat area of the VGT increases with engine speed (Neng) but is constant for a given engine speed.
The four basic control steps during operation are shown in
The flow restricting member may be implemented using any appropriate VGT device, though size, weight and shape requirements make some more suitable than others. Such devices include a sliding wall, sliding annular piston, pivoting vanes and sliding walls with fixed vanes attached. In the pivoting vane arrangement, a series of vanes are arranged around the circumference of the turbine, at the openings where the air stream enters the turbine blades. When the exhaust valves are fully open and the exhaust gas pressure is high, the vanes will be oriented parallel to the air stream, so as not to restrict the openings. At times when exhaust gas pressure is lower, the vanes are pivoted at an acute angle to the air stream, hence restricting the openings to the blades, and increasing gas pressure.
b show one possible pivoting vane ACT arrangement. As shown in
As is shown in
According to this embodiment, the vane ring 600 is constructed with 15 vanes 602 placed equally in a 62 millimetre radius circular ring area. As shown in
As can be seen in
Each vane 602 is inclined in order to match the leading edge of the mixed flow rotor 1202. The inclination angle (considered relative to the surface of the turbine volute 604) is equal to the mixed flow rotor's 1202 cone angle. In the embodiment shown in
It is also possible to retrofit transform a VGT into an ACT by adding an additional flow restrictor or by adding the appropriate control system.
The control system used can be modified in a number of ways; the sensor (300) can be positioned in the conduit (301) between the engine (302) and the mouth of the turbine volute, in the exhaust manifold or in the turbine, and can sense any variable representative of instantaneous turbine inlet pressure, such as mass flow rate. Alternatively, it is possible to actuate the flow restrictor (102) according to the exhaust valve open period, achieved by sending to the ECU the timing signals from different exhaust valve opening and closing based on camshaft rotation. In order to determine the amplitude of the sinusoidal flow restrictor (102) movement, this method still requires either the use of pressure sensor (300) or the calibration of the system before use.
It is also possible to increase the sophistication of the control system by the addition of devices such as a sensor to measure differential pressure across the engine, as well as a LVDT (Linear Variable Differential Transformer) flow restricting member position transducer (304) as shown in
It will be appreciated that the device and components described above can be formed from any appropriate materials and in any appropriate manner. For example the outer guide, inner guide and yoke can be formed from aluminium alloy 6082-T6. The flow restricting member can be constructed from a lightweight material such as carbon fibre reinforced plastic.
The advantage of the invention described over a VGT is that flow area is optimised at all times throughout the driving cycle and steady state pressure within the turbine, for a given engine condition, is approached. This takes advantage of the energy in each gas pulse, resulting in higher mean power extraction from the turbine. The restrictor creates maximum constant pressure at the turbine inlet, which benefits the rotodynamic nature of the turbine. The benefits of operation include improved fuel consumption, higher power output, improved emissions and to a lesser extent improved torque and lag performance. In addition the components are fatigue resistant and lightweight allowing fast response to actuator input in the region of at least 60 Hz for example 20-80 Hz and damping is provided by the pivoting yoke.
Although this description refers mainly to the use of active control flow turbochargers in car engines it is appreciated that the ACT may be used in conjunction with any engine which operates in characteristic cycles.
Number | Date | Country | Kind |
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0426733.2 | Dec 2004 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2005/004663 | 12/6/2005 | WO | 00 | 7/13/2010 |