The present disclosure relates to internal combustion engines. Various embodiments may include a method and a device for adjusting the mass flow of an exhaust-gas recirculation valve of an internal combustion engine which has a turbocharger.
To control an internal combustion engine, a composition of the gas charge and a filling of the combustion chamber with the gas charge are influenced in targeted fashion through setting of actuators such as throttle flaps, exhaust-gas recirculation valves, exhaust-gas flaps, etc. Both the composition and the quantity of the gas charge of the combustion chamber determine not only the amount of injected fuel but also the torque and the combustion products and thus the pollutant quantities in the exhaust gas. The majority of gasoline engines are operated with a stoichiometric combustion gas mixture. This, in conjunction with a three-way catalytic converter, permits an effective reduction of the pollutants formed during the combustion.
The fuel quantity to be injected is in this case determined by the air quantity present in the combustion chamber. In the case of a diesel engine, in nominal operation, the air quantity present constitutes a limitation for the fuel quantity to be injected, in order to achieve that the quantity of exhaust-gas particles remains limited. The oxygen concentration is a significant parameter for the generation of nitrogen oxides as a result of the combustion. A reduction of the oxygen concentration of the cylinder charge leads to a reduction in nitrogen oxide emissions.
In modern diesel engines, this is realized by means of exhaust-gas recirculation. This exhaust-gas recirculation may be realized internally through the cylinder of the internal combustion engine, or externally together with a cooling arrangement that may be provided. This external exhaust-gas recirculation may be performed upstream or downstream of the compressor of a turbocharger of the internal combustion engine. The terms “low-pressure exhaust-gas recirculation” or “high-pressure exhaust-gas recirculation” are correspondingly used.
A prerequisite for exhaust-gas recirculation is always that the gas pressure at the branching point is higher than that at the introduction point. In particular in the case of low-pressure exhaust-gas recirculation, this is not adequately possible in all situations. For this reason, to support the exhaust-gas recirculation, additional throttle flaps are installed in order to permit a required increase or a lowering of the gas pressure at the branching point or at the introduction point.
DE 10 2013 209 815 B3 describes a method and a system for controlling an internal combustion engine which is equipped with an exhaust-gas turbocharger and which furthermore has a high-pressure exhaust-gas recirculation arrangement and a low-pressure exhaust-gas recirculation arrangement. Here, on the basis of a physical model, a determination of flow parameters of the gas flow flowing in the system at different points of the gas flow is performed in a manner dependent on a position of an actuating element in the gas flow. These flow parameters include a temperature and/or a pressure. On the basis of the inverted physical model, a position of the actuating element corresponding to a predetermined flow parameter in the cylinder is determined, the actuating element is controlled into the determined position, a deviation of the predetermined flow parameter from the flow parameter of the gas flow in the cylinder is determined, and a calibration of the physical model is performed on the basis of the deviation, wherein the physical model comprises a recirculation of combusted gas into the cylinder, and wherein, furthermore, the flow parameter comprises a gas composition or a gas flow rate of the gas flow in the cylinder. By means of these measures, it is sought to achieve more direct or more exact control of the internal combustion engine.
The teachings of the present disclosure may be embodied in a method and/or a device for adjusting the mass flow flowing through the exhaust-gas recirculation valve of an internal combustion engine, which method and device operate in a stable manner during the operation of the internal combustion engine. For example, some embodiments include a method for adjusting the mass flow of an exhaust-gas recirculation valve, which is mechanically coupled to a throttle flap, of an internal combustion engine which has a turbocharger, having the following steps: ascertaining a first setpoint value which corresponds to a setpoint opening position of the exhaust-gas recirculation valve, ascertaining a second setpoint value which corresponds to a setpoint opening position of the throttle flap, comparing the first setpoint value with the second setpoint value; adjusting the mass flow of the exhaust-gas recirculation valve by means of a variation of the opening position of the exhaust-gas recirculation valve if the first setpoint value is higher than the second setpoint value, and adjusting the mass flow of the exhaust-gas recirculation valve by means of a variation of the opening position of the throttle flap if the second setpoint value is higher than the first setpoint value.
In some embodiments, the first setpoint value, which corresponds to the setpoint opening position of the exhaust-gas recirculation valve, is ascertained in accordance with the following relationship:
In some embodiments, the second setpoint value, which corresponds to the setpoint opening position of the throttle flap, is ascertained in accordance with the following relationship:
In some embodiments, for the ascertainment of the second setpoint value, firstly a pressure setpoint value is determined on the basis of the model of the exhaust-gas recirculation valve, and subsequently the setpoint position of the throttle flap is determined on the basis of the model of the throttle flap.
In some embodiments, for the ascertainment of the second setpoint value, firstly the relationship
{dot over (m)}
EGR,SP
=A
EGR(sEGR,SP)gEGR(evor EGR,enach EGR)
As another example, some embodiments include a device for adjusting the mass flow of an exhaust-gas recirculation valve, which is mechanically coupled to a throttle flap, of an internal combustion engine which has a turbocharger, characterized in that said device has a control unit (188) which is designed to control a method as described above.
Further characteristics of various embodiments of the teachings herein will emerge from the exemplary explanation thereof below on the basis of the figures. In the figures:
In some embodiments, a method for adjusting the mass flow of an exhaust-gas recirculation valve, which is mechanically coupled to a throttle flap, of an internal combustion engine which has a turbocharger, includes:
By means of this approach, in the presence of an exhaust-gas recirculation valve mechanically coupled to a throttle flap, the coupled system composed of throttle flap and exhaust-gas recirculation valve may be activated in a stable manner. Here, the throttle flap and the exhaust-gas recirculation valve are characterized in model-based fashion independently of one another. A direct determination of the mass flow flowing via the exhaust-gas recirculation valve is possible, and the activation is automatically adapted in the event of a variation of the setpoint value. This may be useful in particular in the presence of different operating modes of the internal combustion engine.
In some embodiments, internal combustion engine 100 has a turbocharger 120, which includes an exhaust-gas turbine 130 and a compressor 125. The exhaust-gas turbine 130 is supplied with exhaust gas which is provided from the cylinders 150 of the internal combustion engine 100. Said exhaust gas causes the turbine wheel of the exhaust-gas turbine 130 to be set in rotation. This rotation of the turbine wheel is transmitted via a shaft of the exhaust-gas turbocharger to a compressor wheel of the compressor 125, which is thereby likewise set in rotation. The compressor wheel is provided for compressing a gas mixture which is composed of fresh air and of exhaust gas recirculated via a low-pressure exhaust-gas recirculation arrangement 180. Said fresh air is supplied to the compressor wheel via an air filter 110. The exhaust gas discharged from the exhaust-gas turbine 130 is released to the surroundings via a catalytic converter 158, a particle filter 160, an exhaust-gas flap 162, and a silencer 164.
In some embodiments, between the particle filter 160 and the exhaust-gas flap 162, there is a branching point at which exhaust gas is branched off, which exhaust gas is supplied via the low-pressure exhaust-gas recirculation arrangement 180 to the compressor 125. A cooler 184 and a low-pressure exhaust-gas recirculation valve 186 are provided in said low-pressure exhaust-gas recirculation arrangement 180. The compressed gas mixture is supplied from the outlet of the compressor 125 via a charge-air cooler 135 and a throttle 140 to the cylinders 150 of the internal combustion engine 100.
Furthermore, the internal combustion engine 100 shown in
Furthermore, the internal combustion engine 100 illustrated in
In some embodiments, the low-pressure exhaust-gas recirculation valve 186 and the exhaust-gas flap 162 may be mechanically coupled to one another and can be activated by means of the same control signal. This activation is performed in model-based fashion, as will be discussed in more detail below on the basis of
Said internal combustion engine 100 has a turbocharger 120, which includes an exhaust-gas turbine 130 and a compressor 125. The exhaust-gas turbine 130 is supplied with exhaust gas which is provided from the cylinders 150 of the internal combustion engine 100. Said exhaust gas causes the turbine wheel of the exhaust-gas turbine to be set in rotation. This rotation of the turbine wheel is transmitted via a shaft of the exhaust-gas turbocharger to the compressor wheel of the compressor 125, which is thereby likewise set in rotation. The compressor wheel compresses a gas mixture which is composed of fresh air and of exhaust gas recirculated via a low-pressure exhaust-gas recirculation arrangement 180. Said fresh air is supplied to the compressor wheel via an air filter 110 and a throttle flap 182. The exhaust gas discharged from the exhaust-gas turbine 130 is released to the surroundings via a catalytic converter 158, a particle filter 160, and a silencer 164.
In some embodiments, between the particle filter 160 and the silencer 164, there is a branching point at which exhaust gas is branched off, which exhaust gas is supplied via the low-pressure exhaust-gas recirculation arrangement 180 to the compressor 125. A cooler 184 and a low-pressure exhaust-gas recirculation valve 186 are provided in said low-pressure exhaust-gas recirculation arrangement 180. The compressed gas mixture is supplied from the outlet of the compressor 125 via a charge-air cooler 135 and a throttle 140 to the cylinders 150 of the internal combustion engine 100.
Furthermore, the internal combustion engine 100 shown in
Furthermore, the internal combustion engine 100 illustrated in
The low-pressure exhaust-gas recirculation valve 186 and the throttle flap 182 are advantageously mechanically coupled to one another and can be activated by means of the same control signal. This activation is performed in model-based fashion.
Such a model-based activation of a valve or of a throttle utilizes the known relationship between the gas mass flow and the position or setting of the valve or of the throttle in the presence of known gas characteristics such as temperature, pressure and gas composition upstream and downstream of the valve or of the throttle. For the modelling, it is possible for either the valve on its own or the entire exhaust-gas recirculation path together, to be considered. In general, the dependency of the gas mass flow factorizes into a dependency on the gas characteristics upstream and downstream of the valve and a dependency on the setting of the valve itself, such that the model is given by an equation in the form
{dot over (m)}=A(s)·g(evor,enach)
where {dot over (m)} is the exhaust-gas mass flow, A(s) is the effective opening cross section and g(evor,enach) is a function of the gas characteristics upstream and downstream of the valve. This applies both to the throttle and to the exhaust-gas recirculation valve.
In the case of a separate activation of the exhaust-gas recirculation valve and of the throttle, the throttle may be utilized for adjusting a desired pressure drop across the exhaust-gas recirculation valve or the exhaust-gas recirculation path, and the exhaust-gas recirculation valve may be used for adjusting the desired exhaust-gas recirculation mass flow.
For the situation of throttling on the fresh air side, as shown in
Here,
sEGR,SP is the setpoint position of the exhaust-gas recirculation valve,
AEGR−1 is the inverse function for the effective opening cross section of the exhaust-gas recirculation valve,
{dot over (m)}EGR,SP is the setpoint mass flow through the exhaust-gas recirculation valve, and
gEGR(evorEGR, enachEGR) is a function of the gas characteristics upstream and downstream of the exhaust-gas recirculation valve.
For the situation of throttling on the fresh air side, as shown in
Here,
sTHR,SP is the setpoint position of the throttle flap,
ATHR−1 is the inverse function for the effective opening cross section of the throttle flap,
{dot over (m)}THR,SP is the setpoint mass flow through the throttle flap, and
gTHR(evorTHR,enachTHR) is a function of the gas characteristics upstream and downstream of the throttle flap.
In the case of a joint activation of the exhaust-gas recirculation valve and of the throttle flap, owing to the mechanical coupling of the exhaust-gas recirculation valve to the throttle flap, the setpoint position of the exhaust-gas recirculation valve already yields the setpoint position of the throttle flap, and vice versa. If the setpoint position of the exhaust-gas recirculation valve is determined by means of the above equation (1), then the setpoint position of the throttle flap is thus already defined. Since, however, in the case of throttling on the fresh-air side, a variation of the position of the throttle flap generally causes the gas pressure downstream of the throttle flap to also be varied, a new value for the gas state enachEGR results. This type of activation therefore generally leads to an undesired, unstable activation behavior, because enachEGR is dependent on sEGR. In principle, it would be necessary to determine sEGR,SP from the solution to the equation
Here, the dependency of enachEGR(sEGR,SP) is given by the equations
{dot over (m)}
THR
=A
THR(sTHR)·gthr(evorTHR,enachTHR) and
s
THR
=s
EGR.
Here,
{dot over (m)}THR is the gas mass flow through the throttle flap,
ATHR is the effective opening cross section of the throttle flap,
sTHR is the position of the throttle flap, and
sEGR is the position of the exhaust-gas recirculation valve.
Since the implicit equation (3) cannot be rearranged into an explicit equation for the setpoint position, a cumbersome iterative solution procedure would be necessary in order to solve the equation (3) and thus determine the setpoint position. To avoid this, the following relationship is utilized: In the case of an only small degree of opening of the exhaust-gas recirculation valve, the throttle flap is either not closed at all or is closed only to a very small degree. The small degree of opening of the exhaust-gas recirculation valve leads to a large change in the recirculated exhaust-gas mass flow. The small degree of closure of the throttle flap leads to only a small change, or no change at all, in the gas pressure downstream of the throttle point. The determination of the setpoint position for the exhaust-gas recirculation valve by means of the stated equation (1) is thus stable.
In the case of the exhaust-gas recirculation valve being opened to a very great extent, the change in the geometrical cross-sectional area of the exhaust-gas recirculation valve alone does not result in a significant change in mass flow. By contrast, as a result of the mechanical coupling of the exhaust-gas recirculation valve to the throttle flap, the throttle flap is almost closed, which leads to an intense change in the pressure downstream of the throttle point. In the case of throttling on the exhaust-gas side, as illustrated in
The effective opening cross-sectional area of the exhaust-gas recirculation valve and of the throttle flap as a function of the joint position or setting of the valve will be illustrated below.
Now, the pressure setpoint value in enach THR,SP from equation (2) will be determined by means of the relationship
{dot over (m)}
EGR,SP
=A
EGR(sEGR,SP)gEGR(evor EGR,enach EGR) (4)
by solving for enachEGR. In the case of throttling on the fresh-air side, as shown in
For a small recirculated setpoint mass flow, equation (1) yields a setpoint position with a cross-sectional area of the exhaust-gas recirculation valve smaller than AEGR,p-controlled. The setpoint position for the throttle flap, which is determined by means of the pressure setpoint value downstream of the throttle and the exhaust-gas recirculation valve assuming a wide-open exhaust-gas recirculation valve AEGR,p-controlled, is now lower than the setpoint position determined using equation (1). The system composed of exhaust-gas recirculation valve and throttle flap is in an operating range in which the mass flow across the exhaust-gas recirculation valve can be set substantially by means of the cross-sectional area of the exhaust-gas recirculation valve.
If, by contrast, for a relatively large recirculated setpoint mass flow, equation (1) yields a setpoint position which corresponds to a cross-sectional area larger than AEGR,p-controlled, then the setpoint position determined using equation (2) will yield a higher setpoint position sTHR,SP, because a relatively small cross-sectional area AEGR,p-controlled was indeed taken as a starting point for the pressure setpoint value determination. Thus, the mass flow across the exhaust-gas recirculation valve is now determined substantially by the required pressure drop across the throttle point.
With this method, the coupled system composed of throttle flap and exhaust-gas recirculation valve may be activated in a stable manner. Here, both flaps—the throttle flap and the exhaust-gas recirculation valve—are physically characterized in model-based fashion substantially independently of one another. A direct determination of the mass flow across the exhaust-gas recirculation valve is possible, and the activation is automatically adapted in the event of a variation of the setpoint value. This is may be used in particular in the case of different operating modes of the internal combustion engine.
In some embodiments, two different ranges are used in order to convert the setpoint mass flow for recirculation into a suitable valve position, specifically a mass flow activation range, in which the setpoint position is obtained directly from the model of the exhaust-gas recirculation valve (equation 1), and a pressure activation range, in which firstly a pressure setpoint value downstream of the exhaust-gas recirculation valve is determined on the basis of the model of the exhaust-gas recirculation valve according to equation 4, and then a setpoint position for the throttle flap is determined from the model of the throttle flap (equation 2). The required switch between these two ranges is performed by means of the above-described selection of the maximum of the cross-sectional area.
Number | Date | Country | Kind |
---|---|---|---|
10 2016 206 554.8 | Apr 2016 | DE | national |
This application is a U.S. National Stage Application of International Application No. PCT/EP2017/057824 filed Apr. 3, 2017, which designates the United States of America, and claims priority to DE Application No. 10 2016 206 554.8 filed Apr. 19, 2016, the contents of which are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/057824 | 4/3/2017 | WO | 00 |