Reference is made to French Patent Application No. 11/03.114, filed on Oct. 12, 2011, which application is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to engine control and more particularly to the control of the burnt gas recirculation rate for a gasoline engine provided with an exhaust gas recirculation circuit (EGR circuit).
2. Description of the Prior Art
Downsizing gasoline engines currently appears to be the preferred option for reducing the consumption of fuel. In fact, this technology allows shifting the working points of the engine to zones of higher efficiency and thus to limit the pumping losses inherent in the operation of an internal-combustion engine. This type of engine then requires the presence of a compressor driven by a turbine arranged in the exhaust line. Such a device is used to improve air filling of the cylinder and to provide a torque equivalent to that of an engine of conventional displacement. It is thus possible to have the same performances of a conventional displacement engine while drastically reducing the consumption.
However, using such a technology greatly increases the risk of engine knocking. When the engine runs under full load conditions, the thermodynamic conditions in the combustion chamber may be detrimental to the stability of the mixture and generate auto-ignition thereof. This phenomenon can eventually greatly deteriorate the combustion chamber.
To solve this problem, the ignition advance is usually degraded. This option generates an increase in the gas temperature at the end of the combustion cycle and therefore over the entire exhaust line. Thus, in order to compensate for this phenomenon, the mixture is richened at the intake.
Such a method involves two drawbacks: which are increasing the engine consumption and furthermore, it deteriorates the efficiency of the catalyst arranged downstream from the exhaust manifold, which provides optimal conversion of the pollutants resulting from the combustion when the mixture is in stoichiometric proportions.
In this context, exhaust gas recirculation (EGR) from the exhaust to the intake is a promising option. Indeed, feeding burnt gas that has not reacted during combustion into a cylinder of the engine allows decreasing the overall combustion temperature and to limit engine knocking. The advantages of downsizing in terms of efficiency and consumption are thus preserved. Besides, introduction of burnt gas also allows reduction of the temperature of the exhaust gas and therefore limiting the impact thereof on the catalyst or the turbine.
However, such a strategy has a great influence on the overall running conditions of the engine. For example, the air mass trapped in the cylinder is smaller in an EGR configuration since burnt gas takes the place of fresh air in the cylinder. To operate under stoichiometric conditions, it is necessary to adjust the fuel loop to the air loop, and thus to control very precisely the amount of burnt gas in the cylinder. Besides, a high-performance control method is essential for torque transient management, notably at low loads where too high a proportion of burnt gas can extinguish the combustion.
To control the amount of burnt gas, current systems (described for example in patent applications FR-2,947,007 A1, EP-2,098,710 A1 and EP-0,485,089 A2) use an air flow detector, which has the drawback of being imprecise. The imprecisions of this detector do not allow optimum control of the composition of the gas in the intake manifold and thus operation under stoichiometric conditions, which generates imprecisions regarding engine control and influences the overall running conditions of the engine.
Control of the mixture composition at the intake is an essential component of the combustion control of supercharged gasoline engines.
The goal of the present invention is to provide an alternative method allowing control in real time of the composition of the gas at the intake for an engine equipped with a pressure difference detector. This pressure difference detector affords the advantage of increasing the precision of the measured values and therefore also of increasing the engine control precision. Using such a detector requires applying a punctual pressure drop relation. Thus, an EGR valve is controlled to observe a burnt gas function set point.
The method according to the invention relates to a method of controlling a combustion engine comprising at least one cylinder and an intake manifold, the engine being equipped with a exhaust gas recirculation circuit integrating an EGR valve.
According to the invention, the control method comprises the following stages:
In one embodiment, the pressure drop relation is adapted to the engine by an air loop model, which is a dynamic model of the air intake circuit and of the EGR burnt gas recirculation circuit. In this case, the model of the air loop can be a model of the burnt gas dynamics and of a static cylinder filling model integrated in a dynamic model of the intake manifold.
Advantageously, the air loop model can be constructed by carrying out the following stages:
Preferably, a pressure drop relation is used which defines an effective surface area set point Ssp(ΔP) for the valve as a function of pressure difference ΔP in a portion of the exhaust gas recirculation circuit including the EGR valve and of the burnt gas fraction set point BGRsp in the intake manifold, then the effective valve surface area set point Ssp(ΔP) is expressed as an opening set point Osp of the EGR valve from a map of the valve.
In an embodiment, the fresh gas and burnt gas mixing dynamics model is defined by the formula as follows:
with BGRbp being the burnt gas fraction in the volume downstream from the EGR valve;
Moreover, the gas transport dynamics model can represent a spatial distance between the EGR valve and the intake manifold of the engine, and it corresponds to a pure delay.
Furthermore, the pressure drop relation can be based on a Barré-Saint Venant relation, linearized for the small pressure difference values ΔP in the portion of the exhaust gas recirculation including the EGR valve, which satisfy the inequality ΔP<10%Patm.
Advantageously, the pressure difference at the EGR valve is measured by at least one pressure detector upstream and/or downstream from the EGR valve.
Preferably, selection of the burnt gas fraction set point BGRsp in the intake manifold is determined by an engine map resulting from a static calibration.
Furthermore, the invention relates to a combustion engine comprising at least one cylinder and an intake manifold, the combustion engine being provided with a exhaust gas recirculation circuit comprising an EGR valve equipped with a pressure difference detector in a portion of the exhaust gas recirculation circuit including the EGR valve, the engine comprising control means for controlling the engine, the control means applying the control method according to the invention.
Other features and advantages of the method according to the invention will be clear from reading the description hereafter of non limitative embodiment examples, with reference to the accompanying figures wherein:
The exhaust gas recirculation circuit withdraws burnt gas at the engine exhaust, at the outlet of catalyst (11), downstream from the turbine of turbocharger (7), and reinjects it into the intake of a cylinder (2) upstream from the compressor of turbocharger (7). The amount of burnt gas reinjected into the intake line is controlled by controlled EGR valve (6) arranged downstream from the EGR burnt gas recirculation circuit.
Since a gasoline engine runs under optimum conditions when the proportion of air/gasoline mixture allows providing complete combustion of the fuel without excess air, it is generally considered that the exhaust gas fully is burnt gas. Thus, the EGR burnt gas recirculation circuit is filled with burnt gas only.
The method according to the invention allows precisely controlling the EGR valve (6) of an exhaust gas recirculation circuit. It is based on the use of a pressure difference detector at the EGR valve and on the application of a pressure drop relation at the level of the EGR valve.
The method according to the invention comprises the following stages:
In the description, the terms upstream and downstream are defined with respect to the direction of flow of the fluids in air loop (10). Furthermore, the following notations are used:
Padm and Tadm are the pressure and the temperature in the intake manifold. Conventionally, the intake temperature is considered to be constant. Indeed, the exchanger arranged upstream from the manifold is so dimensioned as to provide such a regulation.
Patm and Tatm are the atmospheric pressure and the temperature. They can be considered to be constant.
Tam is an upstream temperature at the EGR valve inlet. This temperature is caused by the temperature of the passage through exchanger (4′) arranged in the burnt gas recirculation circuit.
Vbp is the fresh air and burnt gas mixing space, downstream from the EGR valve. It is the volume occupied by the lines at the intersection of the fresh air delivery lines and the burnt gas delivery lines. This space extends up to the compressor of turbocharger (7). This space corresponds to the hatched zone (12) of
Φadm and Φech are the position of the intake (8) and exhaust (9) valve actuators. These variables quantify a phase difference with respect to a reference position.
Ne is engine speed.
BGR is the burnt gas mass fraction in the intake manifold. It conditions the mass of burnt gas present in the cylinder upon closure of the intake valve.
BGRbp is the burnt gas mass fraction in the volume downstream from the EGR valve.
Dthr is the mass flow rate passing through air cooler (4).
Dgb is the mass flow rate of burnt gas fed through EGR valve (6).
Dair is the fresh air mass flow rate at the intake line inlet.
Dasp is the mass flow rate of cylinder filling.
S is the effective surface area of the EGR valve. This quantity characterizes the amount of fluid that can flow through the valve and it is linked with the opening of the valve via a characteristic map of the valve considered.
τ is the gas transport delay between the time of fresh air and burnt gas mixing, and the delivery in the intake manifold.
Pam is the upstream pressure at the EGR valve inlet.
Pav is the downstream pressure at the EGR valve outlet.
ΔP is the pressure difference between upstream and downstream from the EGR valve: ΔP=Pam−Pav. This quantity can be measured with the instrumentation of the EGR valve.
O is the valve opening. This quantity characterizes the valve opening ratio.
r is the specific ideal gas constant, which is the same for all the gases concerned here (exhaust gas and air), and has the value 288 J/kg/K.
γ is gas specific heat ratio. The gases are assumed to be ideal and this ratio is an identical constant for all the gases concerned with the value 1.4.
These notations, with index —sp, represent the set points associated with the quantities considered.
In order to control EGR valve (6) in a precise manner, according to the invention, an EGR valve control method is used depending on pressure difference ΔP in a portion of the exhaust gas recirculation circuit including the EGR valve (6). In an embodiment, this value can be known using a pressure difference detector (5) at the EGR valve (6). Alternatively, two distinct detectors can be used, measuring respectively the pressure at the valve inlet Pav and the pressure at the valve outlet Pam. It is also possible to arrange pressure detectors at other points of air loop (10) and to deduce the value of ΔP from the measured values.
For optimum engine control, a burnt gas fraction set point is selected in the intake manifold BGRsp. To select this set point BGRsp, an engine map resulting from a static calibration or a burnt gas control strategy in a combustion engine can be used. In order to save time during the progress of the method, this stage is preferably conducted simultaneously with the stage of measuring the pressure difference at the EGR valve (6).
To calculate the EGR valve opening set point, a relation of a pressure drop in a portion of the exhaust gas recirculation circuit including the EGR valve is used. This relation allows determination of the valve opening set point Osp as a function of pressure difference ΔP at the level of EGR valve (6) and of burnt gas fraction set point in the intake manifold BGRsp. Preferably, the pressure drop relation is based on a Barré-Saint Venant relation applied to a portion of the exhaust gas recirculation circuit including the EGR valve, and this relation can be linearized for the small values of ΔP (for example for ΔP<10%Patm).
In an embodiment, a pressure drop relation is used depending on pressure difference ΔP at the valve in order to determine an effective surface area set point Ssp(ΔP) for the valve from burnt gas fraction set point BGRsp in the intake manifold. The effective surface area set point Ssp(ΔP) of the valve is then expressed as a valve opening set point Osp from a valve map. An example of such a valve map is illustrated in
Advantageously, the pressure drop relation is adapted to the engine by means of a model of air loop (10), which is a dynamic model of the air intake circuit and of the EGR burnt gas recirculation circuit. Air loop (10) is made up of the intake circuit and of the gas recirculation circuit as a whole. The input data of the air loop model are the engine parameters, burnt gas fraction set point BGRsp, pressure difference ΔP at the EGR valve. In order to control the real behavior of the engine and to create an air loop model as representative as possible, it is important to know some parameters of the engine, that is data characterizing it, and data relative to the operation thereof. These parameters can be measured, simulated and/or obtained from manufacturer's data. The measured or simulated parameters can be the pressure in the intake manifold Padm, the temperature in the intake manifold Tadm, the atmospheric pressure Patm, the atmospheric temperature Tatm, the temperature at the EGR valve outlet Tam, positions φadm and φech of the intake and exhaust valve actuators, and engine speed Ne.
In an embodiment, atmospheric pressure Patm and atmospheric temperature Tatm can be considered to be constants to simplify the model. Moreover, intake temperature Tadm is considered to be constant. Indeed, exchanger (4) arranged upstream from the manifold is so dimensioned as to provide such regulation.
This air loop model can be a model of the burnt gas dynamics and of a static cylinder filling model coupled with a dynamic model of the intake manifold.
In an advantageous embodiment, the air loop model is constructed by carrying out the following stages:
This embodiment of the method is described in its entirety by the flowchart of
After constructing the air loop model, a pressure drop relationship in a portion of the exhaust gas recirculation circuit including the EGR valve is applied. The pressure drop relation is a function of the mass flow rate set point for the burnt gas fed through the EGR valve, Dgbsp .
This model allows calculation of the cylinder filling mass flow rate. An example of such a model has been developed at IFP Energies nouvelles, France, by T. LEROY and J. CHAUVIN, and disclosed in French patent application 2,941,266 A1 corresponding to U.S. Published Application 2010/0180876 A.
The total flow rate passing through the intercooler is estimated. Such an estimation is performed by a static cylinder filling model coupled with a dynamic intake manifold model.
A static filling model estimating the burnt gas mass in the cylinder as a function of the engine speed, the intake temperature and pressure, and the positions of the actuators are considered.
with:
Maspint is the burnt gas mass in the cylinder.
Maspech is the burnt gas mass at the cylinder exhaust.
α1, α2, α3 are known maps, functions of Padm and Ne (experimentally determined on the test bench).
Vivc is the volume of the cylinder upon ivc (intake valve closure), a function of the position of the intake valve actuator Φadm, and of the engine dimensions.
Vevc is the volume of the cylinder upon evc (exhaust valve closure), a function of the position of the exhaust valve actuator Φech, and of the engine dimensions.
OF is the overlap factor. It is a function of the positions of the intake and exhaust valve actuators Φadm and Φech.
From this system of equations, the mass of burnt gas in the cylinder depending on engine parameters Padm, Ne, Φadm and Φech, and on overlap factor OF can be expressed.
The overlap factor OF is determined by the relation:
OF=∫θ
with:
Aadm and Aech are the intake and exhaust valve opening areas which are engine parameters.
θ is the crank angle.
θivo is the crank angle upon ivo (intake valve opening) which is a function of the position of the intake valve actuator Φadm.
θevc is the crank angle upon evc (exhaust valve closure) which is a function of the position of the exhaust valve actuator Φech.
θiv=θev is the crank angle where both valves have the same opening area.
By combining the equations of system (1), a function g between the burnt gas mass as a function of the three parameters Padm, Φadm and Φech can be defined.
The mass flow rate of cylinder filling with air can be determined by the relation (3):
The Equations (2) and (3) are combined and, for the sake of clarity, the engine speed and the intake temperature are disregarded in the expression. Thus, a function f between the cylinder filling mass flow rate and the three parameters Padm, Φadm and Φech is defined.
By modelling the flows passing through the intake manifold, the mass flow rate downstream from the butterfly, Dthr can be calculated, from cylinder filling mass flow rate Dasp and some engine parameters. For example, the equation is expressed as follows:
where Vadm is the volume of the intake manifold.
A function h between the mass flow rate downstream from the butterfly,
Dthr , and the variables Dasp and
can be determined.
Thus, by combining Equations (4) and (5), a function H between the mass flow rate downstream from the butterfly, Dthr, and variables Padm, Φadm, Φech and
can be expressed.
This stage of the method determines the burnt gas fraction set point in the intake manifold. A transport dynamics represents the spatial distance between the actuator and the intake manifold, and corresponds to a pure delay τ variable over time. Modelling of this delay can therefore be written as follows:
BGR(t)=BGRbp(t−τ(t))
By applying this relation to the set points, equality (7) becomes:
BGRsp(t)=BGRbpsp(t−τ(t))
Thus, to control the burnt gas composition in the intake manifold, direct control of the composition in the volume downstream from the EGR valve is accomplished. This stage can be carried out simultaneously with stages i) and ii) to save computation time, or it can be carried out before these stages.
To determine the mass flow rate set point for the burnt gas fed through the EGR valve, Dgbsp, which are the fresh gas and burnt gas dynamics, has to be modelled.
Therefore, the modelling is used as follows (8):
Under steady conditions, Equation (9) is obtained for the flow rates:
Dthr=Dgb+Dair
Thus, by combining Equations (6) to (9), a relation (10) between the mass flow rate set point for the burnt gas fed through the EGR valve and different variables is expressed:
Then, by applying a pressure drop relation in a portion of the exhaust gas recirculation circuit including the EGR valve (for example, the Barré-Saint Venant relation), a relation between the mass flow rate of burnt gas fed through the EGR valve, Dgb , the effective surface area S of the EGR valve, the temperature upstream from the valve, Tam , and the pressure difference at the valve is expressed.
This relation is obtained by applying the Barré-Saint Venant relation for a fluid flowing from a point 1 (upstream) to a point x (downstream), which allows determination of the velocity V of the fluid at point x:
Then, the velocity is related to the mass flow rate by the relation:
The formula as follows is then applied to obtain Equation (11):
To simplify this model, the pressure downstream from the valve is considered to be the atmospheric pressure and the relation below can therefore be expressed only by means of quantity ΔP=Pam−Pav and Patm. In an advantageous embodiment of the invention, this model can be linearized for the small values of ΔP (for example for ΔP<10%Patm). This relation is then reversed to determine a function j between the effective surface area S of the valve and the mass flow rate of burnt gas fed through the EGR valve, Dgb, the temperature upstream from the valve, Tam, and the pressure difference (P at the level of the valve. By writing this relation in terms of set point, the following equality equation is utilized
The effective surface area set point for the EGR valve can therefore be written only as a function of known engine parameters, of the burnt gas fraction set point selected in the intake manifold and of variable ΔP.
Finally, valve opening O is related to effective surface area S by a map characteristic of the valve (
Valve opening set point Osp is then applied to the valve. Manual, hydraulic, pneumatic, electric, electronic or mechanical controls can be selected for the valve.
The control method according to the invention thus allows:
Furthermore, the invention also relates to a combustion engine comprising at least one cylinder and an intake manifold, the combustion engine being provided with a exhaust gas recirculation circuit comprising an EGR valve equipped with a pressure difference detector in a portion of the exhaust gas recirculation circuit including the EGR valve with the EGR valve being controlled, electronically for example, by a method as defined above.
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