Patent Description:
A modern four-stroke direct injection internal combustion engine, such as a diesel engine, is provided with an exhaust gas aftertreatment system in order to fulfil emission legislation, such as the European emission standard Euro <NUM>. An exhaust gas aftertreatment system may comprise e.g. a diesel oxidation catalyst (DOC), a diesel particulate filter (DPF), and a selective catalytic reduction (SCR) device.

A sufficient exhaust gas temperature is required in order to ensure a proper function of the exhaust gas aftertreatment system. A particularly high exhaust gas temperature may be required for regenerating the DPF.

<CIT> discloses a method for regenerating a particulate filter.

<CIT> discloses a control strategy for regenerating a particulate filter in an exhaust system of an engine having a variable valve actuation mechanism. A control for controlling a variable valve actuation mechanism of an internal combustion comprises an operating program for regenerating the particulate filter while the engine is running on its own power, by causing the variable valve actuation mechanism to change the timing of engine cylinder valves during an engine operating cycle, and as a result, elevate the temperature of the gas flow through the exhaust system to a temperature that is effective to combust particles trapped by the particulate filter.

<CIT> discloses a method for operating an internal combustion engine. A particulate filter is arranged in an exhaust system of the internal combustion engine, downstream of an oxidation catalyst. A closing moment of a discharge valve of a cylinder of the internal combustion engine is advanced when the temperature of the oxidation catalyst is in a first temperature range, thus, increasing the temperature of the exhaust gas. An injection valve is utilised to post-inject fuel into at least one cylinder of the internal combustion engine in order to help regenerate a particulate filter. The post-injections are performed when the temperature of the oxidation catalyst is in a second temperature range. An upper limit of the first temperature range having a lower value that an upper limit of the second temperature range.

Not only temperature affects the regeneration of a particulate filter, but also NOx content of the gas flowing through the particulate filter.

It would be advantageous to achieve an alternative method of operating an internal combustion engine, ICE, which method will provide conditions for regenerating a particulate filter of an exhaust gas aftertreatment system connected to the ICE. In particular, it would be desirable to provide for an increased exhaust gas temperature as well as an increase in NOx content of the exhaust gas from an ICE. To better address this, a method of operating a four-stroke direct injection internal combustion engine having the features defined in one of the independent claims, and a four-stroke direct injection internal combustion engine defined in one of the independent claims are provided.

According to an aspect of the invention, there is provided a method of operating a four-stroke direct injection internal combustion engine, ICE, according to claim <NUM>, the engine comprising at least one cylinder arrangement, a crankshaft, and a camshaft. The cylinder arrangement comprises a combustion chamber, a fuel injector, an exhaust valve, a cylinder bore, and a piston configured to reciprocate in the cylinder bore and being connected to the crankshaft. The camshaft is configured to control the opening and closing of the exhaust valve. A timing of the camshaft is controllable. The method comprises:.

Since the method comprises the step of changing the timing of the camshaft to advance the closing of the exhaust valve, the internal load on the ICE is increased and thus, a temperature of the exhaust gas is increased, and since the method comprises the first fuel injecting step during a compression stroke of the piston, increase of NOx content in the exhaust gas is promoted. Moreover, since the method comprises the third fuel injecting step, after the second fuel injecting step, fuel is injected into the combustion chamber, which fuel will not combust in the combustion chamber. Instead the fuel of the third injecting step is entrained with the exhaust gas for promoting exothermal reactions downstream of the exhaust valve and thus, for increasing the temperature of the exhaust gas.

In combination the steps of the method provide for high NOx content high temperature exhaust gas suitable e.g. for regenerating a particulate filter of an exhaust gas aftertreatment system connected to the ICE. The method provides high exhaust gas temperature at zero external load on the ICE. Advancing the closing of the exhaust valve in combination with the refined fuel injection strategy including the first, second, and third fuel injecting steps result in no need for external ICE load enhancing to increase exhaust gas temperature.

The four-stroke direct injection ICE may be a compression ignition ICE, such as a diesel engine. Herein, the four-stroke direct injection ICE simply may be referred to as an internal combustion engine, ICE.

The ICE may form part of a powertrain of a vehicle.

During normal operation of a four-stroke direct injection ICE, a common aim is to reduce the NOx content of the exhaust gas leaving the ICE. Thereby, the amount of NOx which has to be converted into harmless gases by the exhaust gas aftertreatment system connected to the ICE is reduced.

In contrast, the inventors have realised that under certain operating conditions of the ICE, an increased amount of NOx may be beneficial. For instance, if a particulate filter of the exhaust gas treatment system is to be regenerated, i.e. when soot is to be burned off from the particulate filter, NOx contributes to oxidation of the soot which mainly contains carbon, the regeneration resulting in inter alia CO<NUM> forming in the process.

Thus, the method is implemented during regeneration of a particulate filter of an exhaust gas treatment system connected to the ICE. For instance, the method may be implemented when the ICE is not subjected to a high external load, e.g. when the ICE is subjected to low external load, or when a vehicle provided with the ICE is standing still.

Accordingly, the step of changing the timing of the camshaft to advance a closing of the exhaust valve provides an internal load on the ICE, which increases exhaust gas temperature compared to an ordinary timing of the camshaft. Put differently, the ICE itself produces an auxiliary load while the torque on the ICE output shaft is zero. Advancing the closing of the exhaust valve reduces the gas exchange in the cylinder bore and the combustion chamber, i.e. pumping work of the ICE is increased. The increased pumping work is overcome by adding fuel, which in turn increases exhaust gas temperature.

Alternative measures for regenerating the particulate filter are of course available, such as regeneration utilising high temperature exhaust gas produced during high external load operation of the ICE, e.g. when a vehicle provided with the ICE is travelling on an uphill gradient. Accordingly, the method may be implemented in situations where regeneration of the particulate filter is desired, or required, but when the ICE is not subjected to high external load.

As in any four-stroke ICE, the piston performs an intake stroke, a compression stroke, a power stroke, and an exhaust stroke in the cylinder bore of the cylinder arrangement. The rotation of the camshaft is synchronized with the crankshaft. The exhaust valve is configured to open and close an exhaust opening leading out of the combustion chamber, through which exhaust opening gas is admitted out of the combustion chamber. The piston is connected to the crankshaft via a connecting rod.

The cylinder arrangement comprises an intake valve which is configured to open and close an intake opening leading into the combustion chamber, through which intake opening gas is admitted into the combustion chamber. The ICE may comprise more than one cylinder arrangement, such as e.g. four, five, six, or eight cylinder arrangements.

Each of the first, second, and third fuel injecting steps involves fuel injection into the combustion chamber with the fuel injector. Each of the first, second, and third fuel injecting step comprises at least one individual fuel injecting operation. One or more of the first, second, and third fuel injecting steps may comprise two or more individual fuel injecting operations. Each individual fuel injecting operation is performed with the fuel injector.

The timing of the camshaft being controllable entails that the rotational position of the camshaft in relation to the crankshaft is changeable. This may also be referred to as cam phasing. In practice, this means that the crankshaft angle at which a valve controlled by the camshaft is opened and closed can be changed.

The step of changing the timing of the camshaft to advance a closing of the exhaust valve may be performed in any known manner. For instance, <CIT> and <CIT> disclose suitable timing control arrangements to be utilised for changing the timing of the camshaft. Other variable valve timing technology which changes the timing of the camshaft may alternatively be used.

The amount of timing change of the camshaft may be one fixed amount of timing change or a variable amount of timing change providing at least two different amounts of timing change to provide different levels of internal load on the ICE and thus, different levels of temperature increase of the exhaust gas.

Herein, reference will be made to crankshaft angle, CA, degrees when discussing timing of fuel injecting steps, and timing changes of the camshaft. One full rotation of the crankshaft is <NUM> CA degrees. Crankshaft angle is measured from Top Dead Centre fire, TDCf, the TDC between the compression stroke and of the power stroke, i.e. TDCf is <NUM> CA degrees. Negative values of CA are before TDCf, also referred to as BTDCf, positive values of CA are after TDCf, also referred to as ATDCf.

If the ICE comprises more than one exhaust valve, the step of changing the timing of the camshaft to advance the closing of the exhaust valve encompasses advancing the closing of all exhaust valves. Accordingly, if additional exhaust valves are controlled by additional camshafts, also the timing any additional camshafts have to be changed.

According to embodiments, the first fuel injecting step may comprise at least two individual fuel injecting operations. In this manner, the first individual fuel injecting operation will set off early combustion and NOx production and the second individual fuel injecting operation promotes further NOx production in the exhaust gas by supporting the combustion awaiting the second fuel injecting step taking place during the power stroke. In a similar manner, a third individual fuel injecting operation may support the combustion during the compression stroke awaiting the second fuel injecting step.

According to the claimed invention, the third fuel injecting step takes place after opening of the exhaust valve during the power stroke. In this manner, the fuel injected during the third fuel injecting step may be entrained with the exhaust gas escaping through the exhaust valve and further downstream to the aftertreatment system where exhaust temperature may be further increased by exothermal reactions.

The second fuel injecting step comprises at least two individual fuel injection operations. In this manner, the first individual fuel injecting operation may form the main source of combustion energy while the second individual fuel injecting operation may increase exhaust gas temperature.

According to embodiments, wherein the ICE comprises an exhaust gas aftertreatment system, which comprises a first selective catalytic reduction, SCR, device and downstream thereof a particulate filter, the method may comprise:.

According to the claimed invention, the first fuel injecting step is performed within a range of - <NUM> to - <NUM> CA degrees in relation to <NUM> CA degrees being at TDCf, i.e. <NUM> - <NUM> CA degrees BTDCf. In this manner, NOx content of the exhaust gas may be increased by combustion during the compression stroke. At least one individual fuel injecting operation of the first fuel injecting step may be performed within the above defined - <NUM> to - <NUM> CA degrees. However, all individual fuel injecting operations of the first fuel injecting step may be performed within the above defined - <NUM> to - <NUM> CA degrees.

A second individual fuel injection operation subsequent to a first individual fuel injection operation of the second fuel injecting step is performed within a range of <NUM> - <NUM> CA degrees in relation to <NUM> CA degrees being at TDCf, i.e. <NUM> - <NUM> CA degrees ATDCf. In this manner, the second individual fuel injection operation provides for an exhaust gas temperature increase.

According to a further aspect of the invention, there is provided a four-stroke direct injection internal combustion according to claim <NUM>, the engine comprising at least one cylinder arrangement, a crankshaft, a camshaft, and a control system. The cylinder arrangement comprises a combustion chamber, a fuel injector, an exhaust valve, a cylinder bore, and a piston configured to reciprocate in the cylinder bore and being connected to the crankshaft. The fuel injector is controllable by the control system. The camshaft is configured to control the opening and closing of the exhaust valve. A timing of the camshaft is controllable by the control system.

Similarly, as mentioned above in connection with the method, since the control system is configured to change the timing of the camshaft to advance the closing of the exhaust valve, the internal load on the ICE is increased and thus, a temperature of the exhaust gas is increased, and since the control system is configured to control a first fuel injecting step during a compression stroke of the piston, increase of NOx content in the exhaust gas is promoted. Moreover, since the control system is configured to control the third fuel injecting step, after the second fuel injecting step, fuel is injected into the combustion chamber, which fuel will not combust in the combustion chamber. Instead the fuel of the third injecting step is entrained with the exhaust gas for promoting exothermal reactions downstream of the exhaust valve and thus, for increasing the temperature of the exhaust gas.

In combination, the control measures of the control system provide for high NOx content high temperature exhaust gas suitable e.g. for regenerating a particulate filter of an exhaust gas aftertreatment system connected to the ICE. High exhaust gas temperature is provided for at zero external load on the ICE. Advancing the closing of the exhaust valve in combination with the refined fuel injection strategy including the first, second, and third fuel injecting steps result in no need for external ICE load enhancing.

According to a further aspect of the invention, there is provided a vehicle comprising a four-stroke direct injection internal combustion engine according to any one of aspects and/or embodiments discussed herein.

The vehicle may be a heavy load vehicle such as e.g. a truck, a bus, a construction vehicle, a pickup, a van, a train engine, or other similar motorized manned or unmanned vehicle, designed for land-based propulsion, on or off road.

According to a further aspect of the invention, there is provided a computer program comprising instructions which, when the program is executed by the control system of the engine, cause the control system to carry out the method according to any one of aspects and/or embodiments discussed herein.

According to a further aspect of the invention, there is provided a computer-readable storage medium comprising instructions which, when executed by the control system of the engine, cause the control system to carry out the method according to any one of aspects and/or embodiments discussed herein.

Further features of, and advantages with, the invention will become apparent when studying the appended claims and the following detailed description.

Various aspects and/or embodiments of the invention, including its particular features and advantages, will be readily understood from the example embodiments discussed in the following detailed description and the accompanying drawings, in which:.

Aspects and/or embodiments of the invention will now be described more fully.

<FIG> schematically illustrates a vehicle <NUM> according to embodiments. The vehicle <NUM> may be a heavy goods vehicle, designed for land-based propulsion. The vehicle <NUM> comprises a four-stroke direct injection internal combustion engine, ICE, according to any one of aspects and/or embodiments discussed herein, such as e.g. the ICE discussed below with reference to <FIG>. The ICE forms part of a powertrain of the vehicle <NUM>.

<FIG> schematically illustrates embodiments of an ICE <NUM>. The ICE <NUM> may be configured to form part of a powertrain of a vehicle, such as e.g. the vehicle <NUM> shown in <FIG>.

The ICE <NUM> is a four-stroke direct injection internal combustion engine, such as a compression ignition ICE <NUM>, e.g. a diesel engine. The ICE <NUM> comprises at least one cylinder arrangement <NUM>, a crankshaft <NUM>, a camshaft <NUM>.

The cylinder arrangement <NUM> comprises a combustion chamber <NUM>, a fuel injector <NUM>, an exhaust valve <NUM>, a cylinder bore <NUM>, and a piston <NUM> configured to reciprocate in the cylinder bore <NUM>. The piston <NUM> is connected to the crankshaft <NUM> via a connecting rod <NUM>. The movement of the exhaust valve <NUM> is controlled by the camshaft <NUM>, i.e. the camshaft <NUM> is configured to control the opening and closing of the exhaust valve <NUM>.

The ICE <NUM> comprises a further camshaft <NUM> and the cylinder arrangement <NUM> comprises an intake valve <NUM>. The movement of the intake valve <NUM> is controlled by the further camshaft <NUM>.

The intake valve <NUM> is configured for admitting gas into the combustion chamber <NUM>, and the exhaust valve <NUM> is configured for admitting gas out of the combustion chamber <NUM>. At least the timing of the camshaft <NUM> is configured to the be controlled by a timing control arrangement <NUM> as indicated by a double arrow.

In a known manner, the piston <NUM> is arranged to reciprocate in the cylinder bore <NUM>. The piston <NUM> performs four strokes in the cylinder bore <NUM>, corresponding to an intake stroke, a compression stroke, a power stroke, and an exhaust stroke, see also <FIG>. In <FIG> the piston <NUM> is illustrated with continuous lines at its Bottom Dead Centre, BDC, and with dashed lines at its Top Dead Centre, TDC. The combustion chamber <NUM> is formed above the piston <NUM> inside the cylinder bore <NUM>.

In a known manner, the intake valve <NUM> comprises an intake valve head configured to seal against an intake valve seat extending around an intake opening <NUM>. An inlet conduit <NUM> for resh gas, such as air, leads to the intake opening <NUM>. The exhaust valve <NUM> comprises an exhaust valve head configured to seal against an exhaust valve seat extending around an exhaust opening <NUM>. An exhaust conduit <NUM> leads from the exhaust opening <NUM> towards an exhaust system <NUM> connected to the ICE <NUM>.

In a known manner, the camshafts <NUM>, <NUM> rotate at half the rotational speed of the crankshaft <NUM> and control the movement of the intake and exhaust valves <NUM>, <NUM> via lobes <NUM>, <NUM> arranged on the camshafts <NUM>, <NUM>. The camshaft <NUM> is arranged for controlling movement of the exhaust valve <NUM>, and opening and closing of the exhaust opening <NUM>. The camshaft <NUM> comprises a lobe <NUM> configured to abut against the exhaust valve <NUM>. Thus, the exhaust valve <NUM> will follow a contour of the lobe <NUM>. The exhaust valve <NUM> may be biased towards its closed position, e.g. by means of a non-shown spring. The movement of the intake valve <NUM> is controlled in the same manner by the further camshaft <NUM> and its lobe <NUM>.

The cylinder arrangement <NUM> has a total swept volume, VS, in the cylinder bore <NUM> between the BDC and the TDC. According to some embodiments, the cylinder arrangement <NUM> may have a total swept volume, VS, of within a range of <NUM> to <NUM> litres. Mentioned purely as an example, in the lower range of Vs, the cylinder arrangement <NUM> may form part of an internal combustion engine for a passenger car, and in the middle and higher range of Vs, the cylinder arrangement <NUM> may form part of an internal combustion engine for a heavy load vehicle such as e.g. a truck, a bus, or a construction vehicle.

The ICE <NUM> comprises a control system <NUM>. The control system <NUM> is configured to control at least fuel injection into the combustion chamber <NUM> and the timing of the camshaft <NUM>. Thus, the fuel injector <NUM> and the timing control arrangement <NUM> are controllable by the control system <NUM>.

<FIG> illustrates a control system <NUM> to be utilised in connection with the different aspects and/or embodiments of the invention. The control system <NUM> is also indicated in <FIG>. The control system <NUM> comprises at least one calculation unit <NUM>, which may take the form of substantially any suitable type of processor circuit or microcomputer, e.g. a circuit for digital signal processing (digital signal processor, DSP), a Central Processing Unit (CPU), a processing unit, a processing circuit, a processor, an Application Specific Integrated Circuit (ASIC), a microprocessor, or other processing logic that may interpret and execute instructions. The herein utilised expression "calculation unit" may represent a processing circuitry comprising a plurality of processing circuits, such as, e.g., any, some or all of the ones mentioned above. The control system <NUM> comprises a memory unit <NUM>. The calculation unit <NUM> is connected to the memory unit <NUM>, which provides the calculation unit <NUM> with, e.g. stored programme code, data tables, and/or other stored data which the calculation unit <NUM> needs to enable it to do calculations and to control the ICE and optionally an exhaust gas aftertreatment system connected to the ICE. The calculation unit <NUM> is also adapted to store partial or final results of calculations in the memory unit <NUM>. The memory unit <NUM> may comprise a physical device utilised to store data or programs, i.e. sequences of instructions on a temporary or permanent basis. According to some embodiments, the memory unit <NUM> may comprise integrated circuits comprising silicon-based transistors. The memory unit <NUM> may comprise e.g. a memory card, a flash memory, a USB memory, a hard disc, or another similar volatile or non-volatile storage unit for storing data such as e.g. ROM (Read-Only Memory), PROM (Programmable Read-Only Memory), EPROM (Erasable PROM), EEPROM (Electrically Erasable PROM), etc. in different embodiments.

The control system <NUM> is further provided with respective devices <NUM>, <NUM>, <NUM>, <NUM> for receiving and/or sending input and output signals. These input and output signals may comprise waveforms, pulses or other attributes, which can be detect as information by signal receiving devices, and which can be converted to signals processable by the calculation unit <NUM>. Input signals are supplied to the calculation unit <NUM>. Output signal sending devices <NUM>, <NUM>, <NUM> are arranged to convert calculation results from the calculation unit <NUM> to output signals for conveying signal receiving devices of other parts of the control system <NUM>. Each of the connections to the respective devices for receiving and sending input and output signals may take the form of one or more from among a cable, a data bus, e.g. a CAN (controller area network) bus, a MOST (media orientated systems transport) bus or some other bus configuration, or a wireless connection. In the embodiment depicted, only one calculation unit <NUM> and memory <NUM> are shown, but the control system <NUM> may alternatively comprise more than one calculation unit and/or memory.

Mentioned as examples, the output signal sending devices <NUM>, <NUM> may send control signals to the fuel injector <NUM> and to a timing control arrangement <NUM> of the camshaft <NUM>. The input signal receiving device <NUM> may receive signals from the ICE, such as from a rotational speed sensor sending signals related to the rotational speed of the crankshaft of the ICE to the calculation unit <NUM>.

An example of a data table may be a table containing fuel injection quantities. Examples of data may be measured, monitored, and/or calculated data. The control system <NUM> is connected to various sensors and actuators in order to receive input and provide output for performing the various aspects and embodiments of the method discussed herein. An example of a sensor may be a rotational speed sensor. An example of an actuator may a fuel injector.

In the following reference is made to <FIG> and <FIG>. For instance, when a particulate filter of an exhaust gas aftertreatment system connected to the ICE <NUM> is to be regenerated, the control system <NUM> is configured to:.

The third fuel injecting step takes place after opening of the exhaust valve <NUM> during the power stroke. In this manner, fuel injected during the third fuel injecting step may be entrained with the exhaust gas out of the combustion chamber <NUM>. Thus, the fuel injected during the third fuel injecting step may flow downstream of the exhaust valve <NUM> and the exhaust opening <NUM> to increase exhaust gas temperature in the exhaust system of <NUM> connected to the ICE <NUM>.

The exhaust gas increasing measures of changing the timing of the camshaft <NUM> to advance the closing of the exhaust valve <NUM>, and/or the first fuel injecting step during the compression stroke of the piston <NUM>, and/or the second fuel injecting step during the power stroke of the piston <NUM> promote exothermal reactions downstream of the exhaust valve <NUM> energised by the fuel injected in the third fuel injecting step.

According to embodiments, the third fuel injecting step may take place within a range of <NUM> - <NUM> CA degrees after opening the exhaust valve <NUM> during the power stroke.

The change of the timing of the camshaft <NUM> to advance the closing of the exhaust valve comprises advancing the closing of the exhaust valve <NUM> at least <NUM> CA degrees from an ordinary exhaust valve closing. In this manner, an internal load is put on the ICE <NUM>, which increases exhaust gas temperature.

The ordinary closing of the exhaust valve <NUM> is that, at which the exhaust valve <NUM> closes during normal operation of the ICE <NUM>, i.e. when the ICE <NUM> produces positive torque on its output shaft to drive e.g. a vehicle.

<FIG> illustrates a diagram over functionality the ICE <NUM> of <FIG>. <FIG> illustrates the four strokes of the piston <NUM> and the movement of the exhaust valve and of the intake valve. The movement of the intake valve is indicated with a dash-dotted line. The movement of the exhaust valve during ordinary operation of the ICE is indicated with a full line.

The crankshaft of the ICE rotates <NUM> CA degrees as the four strokes of the piston <NUM> are performed. For each stroke, the crankshaft rotates <NUM> CA degrees as indicated in <FIG>. A represents the intake stroke, B represents the compression stroke, C represents the power stroke, and D represents the exhaust stroke.

The broken line indicates the movement of the exhaust valve after the timing of the camshaft has been changed to advance the closing of the exhaust valve, in accordance with the present invention. In <FIG> α indicates advancing the closing of the exhaust valve, in accordance with the change of the timing of the camshaft discussed above with reference to <FIG> and <FIG>.

In <FIG> the advancing α indicated is approximately <NUM> CA degrees. That is, the exhaust valve will be closed during a large part of the last half of the exhaust stroke.

Mentioned as an example, the ordinary closing of the exhaust valve <NUM> during normal operation of the ICE <NUM> may be within a range of <NUM> - <NUM> CA degrees. In this example, the change of the timing of the camshaft <NUM> to advance the closing of the exhaust valve <NUM> at least <NUM> CA degrees from the ordinary exhaust valve closing means that the closing of the exhaust valve is advanced to <NUM> - <NUM> CA degrees.

<FIG> illustrates different fuel injecting steps into the combustion chamber of the ICE of <FIG>, as discussed above with reference to <FIG> and <FIG>. The different fuel injecting steps are indicated with ovals in <FIG>. The first fuel injecting step is indicated at <NUM>. The second fuel injecting step is indicated at <NUM>. The third fuel injecting step is indicated at <NUM>. In <FIG>, arrows indicated with roman numbers represent individual fuel injecting operations of the first, second, and third fuel injecting steps <NUM>, <NUM>, <NUM>.

In the following reference is made to <FIG> and the discussions above.

According to embodiments, the first fuel injecting step <NUM> may comprise at least two individual fuel injecting operations I, II, III. In this manner, early combustion for increased NOx production is initiated as well as maintained.

In the embodiments of <FIG>, three individual fuel injecting operations I, II, III during the first fuel injecting step <NUM> are provided. The first and second individual fuel injecting operations I, II promote the production of NOx in the exhaust gas, whereas the third individual fuel injecting operation III is provided for maintaining the combustion in the combustion chamber <NUM> until the second fuel injecting step <NUM> during the power stroke of the piston <NUM>.

According to embodiments, a first individual fuel injection operation I of the first fuel injecting step <NUM> may be performed within a range of - <NUM> to - <NUM> CA degrees in relation to <NUM> CA degrees at TDCf, i.e. <NUM> - <NUM> CA degrees BTDCf. In this manner, production of NOx in the exhaust gas may be promoted.

The second fuel injecting step <NUM> comprises at least two individual fuel injection operations IV, V. In this manner, a first individual fuel injecting operation IV of the second fuel injecting step <NUM> may form of the main individual fuel injecting operation for combustion with the aim of producing the main power during the power stroke, where as a second individual fuel injecting operation V of the second fuel injecting step <NUM> may be provided for increasing exhaust gas temperature. In <FIG>, the first individual fuel injecting operation IV is performed shortly after the piston <NUM> has passed TDCf, within a range of <NUM> - <NUM> CA degrees ATDCf, such as at approximately <NUM> CA degrees ATDCf. The second individual fuel injecting operation V is performed later during the power stroke, before the exhaust valve <NUM> has started to open with the timing of the camshaft <NUM> changed for the advanced closing, and thus also advanced opening, of the exhaust valve <NUM>. In <FIG>, the second individual fuel injecting operation V is performed within a range of <NUM> - <NUM> CA degrees ATDCf, such as at approximately <NUM> CA degrees ATDCf.

In the following reference is made to <FIG>. The exhaust system <NUM> comprises an exhaust gas aftertreatment system <NUM>, i.e. an exhaust gas aftertreatment system <NUM> is connected to the exhaust conduit <NUM> of the ICE <NUM>.

Accordingly, according to some embodiments, the internal combustion engine <NUM> may comprise an exhaust gas aftertreatment system <NUM>, which may comprise a first selective catalytic reduction, SCR, device <NUM> and downstream thereof a particulate filter <NUM>. The control system <NUM> may be configured to refrain from injecting urea or ammonia into the first SCR device <NUM>. In this manner, NOx content of the exhaust gas from the ICE <NUM> may be maintained and may be utilised in the particulate filter <NUM> for regeneration thereof.

More specifically, the first SCR device <NUM>, in a known manner, may be configured to reduce NOx content of exhaust gas utilising urea or ammonia. Thus, the first SCR device <NUM> comprises a first dosage device <NUM> configured to inject an additive comprising a urea or ammonia into the exhaust gas stream flowing into, and through, the first SCR device <NUM>. The particulate filter <NUM> may be a diesel particulate filter, DPF, configured for reducing particles in the exhaust gas stream. In accordance with these embodiments, when the particulate filter <NUM> is regenerated, the NOx content of the exhaust gas is not reduced in the first SCR device <NUM> by the control system <NUM> controlling the first dosage device <NUM> to refrain from injecting urea or ammonia into the first SCR device <NUM>. See also <FIG>. Thus, the NOx in the exhaust gas may contribute to the regeneration of the particulate filter <NUM>.

The exhaust gas aftertreatment system <NUM> may further comprise a second SCR device <NUM>. Such an exhaust gas aftertreatment system <NUM>, its operation, and specific advantages, is discussed in detail in <CIT>. During regeneration of the particulate filter <NUM>, any remaining NOx content of the exhaust gas passing the particulate filter <NUM> may be reduced in the second SCR device <NUM>. That is, a second dosage device <NUM> is controlled by the control system <NUM> to inject urea or ammonia into the second SCR device <NUM>.

<FIG> illustrates embodiments of a method <NUM> of operating a four-stroke ICE. The vehicle and the ICE may be a vehicle <NUM> and an ICE <NUM> as discussed above in connection with <FIG>. Accordingly, in the following reference is also made to <FIG> and the descriptions related thereto.

As discussed inter alia above with reference to <FIG>, and the control system <NUM>, the step <NUM> of changing the timing of the camshaft to advance the closing of the exhaust valve, increases the internal load on the ICE increases the exhaust gas temperature, the first fuel injecting step <NUM> during the compression stroke of the piston <NUM> promotes increased NOx content in the exhaust gas, the second fuel injecting step <NUM> provides a main individual fuel injecting operation and optionally an exhaust gas temperature increasing further individual fuel injecting operation, and the third fuel injecting step <NUM> provides fuel which will not combust in the combustion chamber but is entrained with the exhaust gas from the combustion chamber <NUM>.

Particularly, reference is made to the first, second, and third fuel injecting steps <NUM>, <NUM>, <NUM> discussed above with reference to <FIG>, which correspond to the respective first, second, and third fuel injecting steps <NUM>, <NUM>, <NUM> of the method <NUM>.

According to embodiments, the first fuel injecting step <NUM> may comprise at least two individual fuel injecting operations. As discussed above, the first individual fuel injecting operation will set off early combustion and NOx production and the second individual fuel injecting operation promotes further NOx production in the exhaust gas by supporting the combustion awaiting the second fuel injecting step taking place during the power stroke. In a similar manner, a third individual fuel injecting operation may support the combustion during the compression stroke awaiting the second fuel injecting step, see also above with reference to <FIG>.

The third fuel injecting step <NUM> takes place after opening of the exhaust valve <NUM> during the power stroke of the piston <NUM>. As discussed above, the fuel injected during the third fuel injecting step <NUM> may be entrained with the exhaust gas escaping through the exhaust valve to promote exhaust gas temperature increase downstream of the exhaust valve.

The second fuel injecting step <NUM> comprises at least two individual fuel injection operations. As discussed above, the first individual fuel injecting operation of the second fuel injecting step <NUM> may form the main source of combustion energy while the second individual fuel injecting operation may increase exhaust gas temperature.

According to embodiments, the step <NUM> of changing the timing of the camshaft may comprise:.

According to embodiments, wherein the ICE comprises an exhaust gas aftertreatment system, which comprises a first selective catalytic reduction, SCR, device <NUM> and downstream thereof a particulate filter <NUM>, the method <NUM> may comprise:.

The first fuel injecting step <NUM> is performed within a range of - <NUM> to - <NUM> CA degrees in relation to <NUM> CA degrees being at TDCf. As discussed above, NOx content of the exhaust gas may be increased by combustion during the compression stroke. By performing one or more individual fuel injecting operations within the above defined - <NUM> to - <NUM> degrees CA this may be achieved.

A second individual fuel injection operation subsequent to a first individual fuel injection operation of the second fuel injecting step <NUM> is performed within a range of <NUM> - <NUM> degrees crankshaft angle, CA, in relation to <NUM> crankshaft angle, CA, degrees being at TDCf. As discussed above, this provides for an exhaust gas temperature increase.

The method <NUM> may be implemented in situations where regeneration of the particulate filter is desired, or required, but when the ICE <NUM> is not subjected to high external load. In such situations a vehicle comprising the ICE <NUM> may be standing still. This may for instance occur during service of the ICE <NUM> and the vehicle <NUM>.

A further alternative may be to perform the method <NUM> when the ICE <NUM> is subjected to low load, which in itself does not produce a high enough exhaust gas temperature for regenerating a particulate filter.

Mentioned as an example, e.g. in such above discussed situations, the method <NUM> may be performed continuously over a time period having a length within a range of <NUM> - <NUM> minutes. In this manner, the particulate filter <NUM> may be regenerated.

According to an aspect there is provided a computer program comprising instructions which, when the program is executed by control system cause the control system to carry out the method <NUM> according to any one of aspect and/or embodiments discussed herein, in particular with reference to <FIG>. One skilled in the art will appreciate that the method <NUM> of operating a four-stroke ICE may be implemented by programmed instructions. These programmed instructions are typically constituted by a computer program, which, when it is executed in a control system, ensures that the control system carries out the desired control, such as the method steps <NUM> - <NUM> according to the invention. The computer program is usually part of a computer programme product which comprises a suitable digital storage medium on which the computer program is stored.

<FIG> shows a computer-readable storage medium <NUM> according to embodiments. The computer-readable storage medium <NUM> comprises instructions which, when executed by a computer or other control system <NUM>, causes the computer or other control system <NUM> to carry out the method <NUM> according to any one of aspects and/or embodiments discussed herein. The computer-readable storage medium <NUM> may be provided for instance in the form of a data carrier carrying computer program code for performing at least some of the steps <NUM> - <NUM> according to some embodiments when being loaded into the one or more calculation units <NUM> of the control system <NUM>. The data carrier may be, e.g. a ROM (read-only memory), a PROM (programable read-only memory), an EPROM (erasable PROM), a flash memory, an EEPROM (electrically erasable PROM), a hard disc, a CD ROM disc, a memory stick, an optical storage device, a magnetic storage device or any other appropriate medium such as a disk or tape that may hold machine readable data in a non-transitory manner. The computer-readable storage medium may furthermore be provided as computer program code on a server and may be downloaded to the control system <NUM> remotely, e.g., over an Internet or an intranet connection, or via other wired or wireless communication systems.

Claim 1:
A method (<NUM>) of operating a four-stroke direct injection internal combustion engine (<NUM>) during regeneration of a particulate filter of an exhaust gas treatment system connected to the internal combustion engine (<NUM>), the internal combustion engine comprising at least one cylinder arrangement (<NUM>), a crankshaft (<NUM>), and a camshaft (<NUM>),
the cylinder arrangement (<NUM>) comprising a combustion chamber (<NUM>), a fuel injector (<NUM>), an exhaust valve (<NUM>), a cylinder bore (<NUM>), and a piston (<NUM>) configured to reciprocate in the cylinder bore (<NUM>) and being connected to the crankshaft (<NUM>), wherein
the camshaft (<NUM>) is configured to control the opening and closing of the exhaust valve (<NUM>), wherein
a timing of the camshaft (<NUM>) is controllable, and wherein
the method (<NUM>) comprises, in combination:
- a step (<NUM>) of changing the timing of the camshaft (<NUM>) to advance a closing of the exhaust valve (<NUM>),
- a first fuel injecting step (<NUM>) during a compression stroke of the piston (<NUM>),
- a second fuel injecting step (<NUM>) during a power stroke of the piston (<NUM>), and
- a third fuel injecting step (<NUM>), after the second fuel injecting step (<NUM>), during the power stroke of the piston (<NUM>), and wherein
the first fuel injecting step (<NUM>) is performed within a range of - <NUM> to - <NUM> crankshaft angle, CA, degrees in relation to <NUM> crankshaft angle, CA, degrees being at TDCf, and wherein
the second fuel injecting step (<NUM>) comprises at least two individual fuel injection operations (IV, V), and wherein
a second individual fuel injection operation (V) subsequent to a first individual fuel injection operation (IV) of the second fuel injecting step (<NUM>) is performed within a range of <NUM> - <NUM> degrees crankshaft angle, CA, in relation to <NUM> crankshaft angle, CA, degrees being at TDCf, and wherein
the step (<NUM>) of changing the timing of the camshaft (<NUM>) comprises:
- a step (<NUM>) of changing the timing to advance the closing of the exhaust valve (<NUM>) at least <NUM> crankshaft angle, CA, degrees from an ordinary exhaust valve closing, and wherein the third fuel injecting step (<NUM>) takes place after opening of the exhaust valve (<NUM>) during the power stroke.