Patent Description:
Motor vehicles being arranged to be propelled by means of an internal combustion engine are provided with a fuel provision system. According to one variant, a low-pressure fuel circuit of the fuel provision system comprises a feeder pump being arranged to provide fuel to a high pressure pump of the internal combustion engine.

Some drawbacks have been identified regarding the low-pressure fuel circuit. One of them is appearance of a reduction of fuel pressure in the low-pressure fuel circuit of the fuel provision system during gear shifting. This phenomenon occurs due to that fact that the existing regulation strategy is controlling the feeder pump to reduce its speed when the injected amount of fuel to the engine is reduced, which may happen during dragging of the engine, e.g. when driving downhill, but also during gear shifting. The problem is though that the gear shifting sequence is relatively fast and the feeder pump hereby is not always able to increase its speed fast enough to reach a nominal fuel feed pressure after the shifting is performed.

The speed of the feeder feed pump is today regulated on the basis of a prevailing fuel pressure downstream of the feeder pump. The feeder pump speed is controlled in such a way that a constant fuel feed pressure is achieved. There is also an input regarding the amount of fuel injected to the engine. The reason for this is that there is a desire to reduce the feeder pump speed during dragging of the engine. However, during gear shifting the injected amount of fuel is also reduced (e.g. to a zero level), but only for a relatively short amount of time. Hereby the feeder pump is arranged to reduce pump speed, but since the time window for a gear shifting is so short, the feeder pump is not able to increase its speed fast enough again when the shifting sequence has been performed. This may cause discomfort for an operator of the vehicle.

Another issue is that pressure spikes in the fuel provision system occurs during the gear shifting sequence. Since there are so many gear shifting sequences during the life of a truck this can give arise to fatigue problems of the fuel pipes.

<CIT> discloses a method for controlling a low-pressure circuit in fuel system of a vehicle. Hereby controlling of a fuel pump in low-pressure circuit is based on a future working point that is determined based on road ahead information.

The patent application <CIT> discloses that the control of the fuel pump is delayed in order to maintain the speed of the fuel supply pump, when the engine is facing short transition period like the gear shift.

An object of the present invention is to propose a novel and advantageous method for operating a fuel supply pump of a vehicle according to claim <NUM>.

Another object of the invention is to propose a novel and advantageous system according to claim <NUM> and a novel and advantageous computer program according to claim <NUM> for operating a fuel supply pump of a vehicle.

The invention is providing as well a more comfortable operation of the vehicle as a low wear of the components of the fuel supply system and a fully automated and user-friendly operation of a fuel supply pump of a vehicle.

Hereby a prevailing fuel supply pump speed may be maintained at a current level during a gear shifting process of the gearbox. This advantageously provides a more comfortable propulsion of the vehicle since a stable operation without great variations of fuel supply is achieved. This also provides a fuel supply system which is introducing less wear of components of the fuel supply system.

Any one of the steps of the method for operating a fuel supply pump of a vehicle may be performed continuously or intermittently.

By identifying if a gear shifting process of the gearbox is at hand when the injected fuel amount rate is decreased it can be concluded that the vehicle is not dragging. The gear shift process is a relatively short process and advantageously the fuel supply pump rate is not reduced from a current level if a gear step change of the gearbox is at hand.

The fuel supply pump is arranged in a low-pressure circuit of a fuel supply system. The fuel supply pump may be a feeder pump being arranged to provide fuel to a high pressure pump of a combustion engine.

Advantageously the proposed method introduces less vehicle vibrations and reduced vehicle noise emissions during a gear step change.

According to one embodiment it is determined that a gear-step change of the gearbox is at hand if the boost pressure has been determined to be unchanged. According to one embodiment it is determined that a gear-step change of the gearbox is not at hand if the boost pressure has been determined to have changed. According to one embodiment it is determined that a gear-step change of the gearbox is at hand if the Lambda-value has been determined to be unchanged. According to one embodiment it is determined that a gear-step change of the gearbox is not at hand if the Lambda-value has been determined to have changed.

According to one embodiment it is determined that a gear-step change of the gearbox is at hand if both the Lambda-value and the boost pressure have been determined to be unchanged. According to one embodiment it is determined that a gear-step change of the gearbox is not at hand if both the Lambda-value and the boost pressure have been determined to have changed.

The system may comprise means being arranged for, in case a gear step change of the gearbox is not at hand, allowing a change of fuel supply pump speed. The means being arranged for allowing a change of fuel supply pump speed may comprise one of one or more electronic control arrangements.

The means being arranged for determining a boost pressure of the combustion engine system may comprise one or more electronic control arrangements and a boost pressure sensor. The means being arranged for determining that a gear step change of the gearbox is not at hand may comprise one or more electronic control arrangements. The means being arranged for determining a boost pressure may be arranged to determine the boost pressure continuously or intermittently.

The means being arranged for determining a Lambda-value of the combustion engine system may comprise one or more electronic control arrangements and a Lambda-sensor configuration. The means being arranged for determining that a gear step change of the gearbox is at hand may comprise one or more electronic control arrangements. The means being arranged for determining a Lambda-value may be arranged to determine the Lambda-value continuously or intermittently.

For fuller understanding of embodiments of the present invention and its further objects and advantages, the detailed description set out below should be read in conjunction with the accompanying drawings, in which the same reference notations denote similar items in the various diagrams, and in which:.

<FIG> depicts a side view of a vehicle <NUM>. The exemplified vehicle <NUM> comprises a tractor unit <NUM> and a trailer <NUM>. The vehicle <NUM> may be a heavy vehicle, e.g. a truck or a bus. It may alternatively be a car. The vehicle <NUM> comprises a combustion engine system and transmission for propelling the vehicle. The vehicle <NUM> may comprise an internal combustion engine and a multi-step gearbox. The transmission may comprise a clutch being arranged to disengage the gearbox from an outgoing shaft of the combustion engine during a gear-step change of the gearbox.

The method and system are applicable to various vehicles comprising a combustion engine system and transmission for propelling the vehicle, such as e.g. a mining machine, tractor, dumper, wheel-loader, forest machine, earth mover, road construction vehicle, road planner, emergency vehicle or a tracked vehicle. The method and system disclosed herein is applicable to various stationary platforms comprising a combustion engine system and transmission for conveying torque to any application device/system.

The term "link" refers herein to a communication link which may be a physical connection such as an opto-electronic communication line, or a non-physical connection such as a wireless connection, e.g. a radio link or microwave link.

The term "system" is according to one embodiment herein defined as a system comprising only one electronic control arrangement or a number of connected electronic control arrangements. Said one electronic control arrangement or said number of connected electronic control arrangements may be arranged to perform the steps according to the method depicted herein. Herein the term "electronic control arrangement" may be synonymous with an "electronic control unit" (ECU).

The term "combustion engine system" herein refers to a system comprising a combustion engine. Other components of the combustion engine system may be a turbo (boost) unit, an engine inlet passage, an engine outlet passage, etc. According to one embodiment the combustion engine system also comprises a transmission for propelling the vehicle. The transmission comprises a gearbox (not shown).

<FIG> schematically illustrates a fuel supply system <NUM> of the vehicle <NUM>. The system <NUM> is situated in the tractor unit <NUM>.

A first fuel tank <NUM> is arranged to hold a fuel for provision to an engine <NUM> of the vehicle <NUM>. The first fuel tank <NUM> may be referred to as main fuel tank. The engine <NUM> may be any suitable engine, such as an internal combustion engine. The engine <NUM> may comprise a so called Otto-engine or a diesel engine. The fuel is a fluid. The fuel may be a so-called liquid fuel. The fuel may comprise hydrocarbon fuels, various alcohols and/or bio-diesel. The fuel may be a gaseous fuel. The fuel may be a liquefied petroleum gas.

A fuel passage configuration <NUM> is arranged to convey the fuel from the first fuel tank <NUM> via a number of components for provision to the engine <NUM>. A first electronic control arrangement <NUM> is arranged for communication with a first electrical fuel pump <NUM> via a link L231. The first electrical fuel pump <NUM> may be referred to as transfer pump. The first control arrangement <NUM> is arranged to control operation of the first electrical fuel pump <NUM> by means of control signals S231. The first electrical fuel pump <NUM> is arranged to feed the fuel through a first filter unit <NUM>. The first filter unit <NUM> is arranged for water separation and to filter the fuel with regard to larger particles and contamination material.

The fuel passage configuration <NUM> is arranged to convey the fuel from the first fuel tank <NUM> to a second fuel tank <NUM>. The second fuel tank <NUM> may be referred to as catch tank. The catch tank is preferably smaller than the main tank. The first electronic control arrangement <NUM> is arranged for communication with a second electrical fuel pump <NUM> via a link L241. The second electrical fuel pump <NUM> may be referred to as feeder pump. The first control arrangement <NUM> is arranged to control operation of the second electrical fuel pump <NUM> by means of control signals <NUM>. The second electrical fuel pump <NUM> is arranged to feed the fuel through a second filter unit <NUM>. The second filter unit <NUM> is arranged to filter the fuel with regard to finer particles and contamination material.

The feeder pump <NUM> is arranged to provide the fuel to a high pressure pump (HHP) <NUM>. A portion of the fuel supply system <NUM> being arranged upstream of the high pressure pump <NUM> is referred to as a low pressure fuel circuitry. The high pressure pump <NUM> is arranged to provide fuel for controlled injection to combustion chambers of the engine <NUM>. The first control arrangement <NUM> is arranged to control fuel supply to the engine <NUM>. An injected amount of the fuel is herein denoted Qinj. The first control arrangement <NUM> may be adapted to control operation of the engine <NUM> in accordance with stored control routines.

The first electronic control arrangement <NUM> is arranged for communication with a fuel pressure sensor <NUM> via a link L243. The fuel pressure sensor <NUM> is arranged to measure a prevailing fuel pressure Pr of the fuel within the fuel passage configuration <NUM> at a position downstream of the second filter unit <NUM> and upstream of a the high pressure pump <NUM>. The fuel pressure sensor <NUM> is arranged to send signals S243 comprising information about the determined prevailing fuel pressure Pr to the first control arrangement <NUM> via the link L243.

A second control arrangement <NUM> is arranged for communication with the first control arrangement <NUM> via a link L210. It may be releasably connected to the first control arrangement <NUM>. It may be a control arrangement external to the vehicle <NUM>. It may be adapted to perform the steps according to embodiments of the invention. It may be used to cross-load software to the first control arrangement <NUM>, particularly software for applying the method disclosed herein. It may alternatively be arranged for communication with the first control arrangement <NUM> via an internal network on board the vehicle <NUM>. It may be adapted to perform functions corresponding to those of the first control arrangement <NUM>, such as determining whether a gear step change of a gearbox of the vehicle is at hand, on the basis of the thus determined values of the at least one operational parameter. It may be adapted to, in case a gear step change of the gearbox is at hand, controlling operation of the feeder pump <NUM> so as to maintain the speed Prpm of the feeder pump <NUM>.

<FIG> schematically illustrates a portion of a combustion engine system of the vehicle <NUM>. The combustion engine system may comprise a turbo charger unit (not shown). The first control arrangement <NUM> is arranged for communication with a boost pressure sensor <NUM> via a link L271. The boost pressure sensor <NUM> is arranged to measure a prevailing boost pressure Pb in an air intake passage of the engine <NUM>. The boost pressure sensor <NUM> may be arranged to continuously or intermittently measure a prevailing boost pressure Pb in an air intake passage of the engine 250The boost pressure sensor <NUM> is arranged to send signals S271 comprising information about the measured prevailing boost pressure Pb to the first control arrangement <NUM> via the link L271.

The first control arrangement <NUM> is arranged for communication with a Lambda-sensor configuration <NUM> via a link L261. The Lambda-sensor configuration <NUM> is arranged to determine adequate information for determining a prevailing Lambda-value λ relating to engine operation. Here the Lambda-sensor configuration <NUM> is arranged in an outlet passage of the engine <NUM>. The Lambda-sensor configuration <NUM> may be arranged to continuously or intermittently determine a prevailing Lambda-value λ. The Lambda-sensor configuration <NUM> is arranged to send signals S261 comprising the thus determined adequate information for determining the prevailing Lambda-value λ to the first control arrangement <NUM> via the link L261. The Lambda-value λ is known to relate to an Air Fuel Ratio (AFR).

According to one aspect of the disclosure there is provided a system for operating a fuel supply pump <NUM> of a vehicle <NUM>, the vehicle comprising a combustion engine system <NUM> and a gearbox.

According to an example there is provided a system comprising means being arranged for determining values of at least one operational parameter of the combustion engine system <NUM>. The means being arranged for determining values of at least one operational parameter may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM>, the device <NUM> (<FIG>), the boost pressure sensor <NUM> and the Lambda-sensor configuration <NUM>. The at least one operational parameter may be the boost pressure Pb of the combustion engine system <NUM> and/or the Lambda-value λ of the combustion engine system <NUM>.

According to an example there is provided a system comprising means being arranged for determining a change of fuel provision to the combustion engine system <NUM>. The means being arranged for determining a change of fuel provision may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to an example there is provided a system comprising means being arranged for determining whether a gear step change of the gearbox is at hand, on the basis of the thus determined values of the at least one operational parameter. The means being arranged for determining whether a gear step change of the gearbox is at hand may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to an example there is provided a system comprising means being arranged for, in case a gear step change of the gearbox is at hand, controlling operation of the fuel supply pump <NUM> so as to maintain fuel supply pump speed Prpm. The means being arranged for controlling operation of the fuel supply pump <NUM> so as to maintain fuel supply pump speed Prpm may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to an example there is provided a system comprising means being arranged for, in case a gear step change of the gearbox is not at hand, allowing a change of fuel supply pump speed Prpm. The means being arranged to allow the change of fuel supply pump speed Prpm may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to an example there is provided a system comprising means being arranged for determining a boost pressure Pb of the combustion engine system <NUM>. The means being arranged for determining a boost pressure Pb may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM>, the device <NUM> and the boost pressure sensor <NUM>.

According to an example there is provided a system comprising means being arranged for determining that a gear step change of the gearbox is at hand if the boost pressure Pb is unchanged over time. The means being arranged for determining that a gear step change of the gearbox is at hand may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to an example there is provided a system comprising means being arranged for determining that a gear step change of the gearbox is not at hand if the boost pressure Pb is changed more than to a predetermined extent. The means being arranged for determining that a gear step change of the gearbox is not at hand may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to an example there is provided a system comprising means being arranged for determining a Lambda-value λ of the combustion engine system <NUM>. The means being arranged for determining a Lambda-value λ of the combustion engine system <NUM> may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM>, the device <NUM> and the Lambda-sensor configuration <NUM>.

According to an example there is provided a system comprising means being arranged for determining that a gear step change of the gearbox is at hand if the Lambda-value λ is unchanged over time. The means being arranged for determining that a gear step change of the gearbox is at hand may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to an example there is provided a system comprising means being arranged for determining that a gear step change of the gearbox is not at hand if the Lambda-value λ is changed more than to a predetermined extent. The means being arranged for determining that a gear step change of the gearbox is not at hand may comprise any one of the first control arrangement <NUM>, the second control arrangement <NUM> and the device <NUM>.

According to one example there is provided a vehicle comprising a system according to the disclosure herein.

<FIG> schematically illustrates a signal diagram according to an example embodiment.

The speed Prpm of the feeder pump <NUM> is operated on the basis of the fuel pressure Pr. A signal relating to the injected amount of fuel Qinj to the engine <NUM> is provided. Herein a regulator is arrange to provide the feeder pump speed signal on the basis of:.

Functionality of the signal diagram is depicted in greater detail with reference to e.g. <FIG>.

<FIG> schematically illustrates a diagram wherein three parameters are given as a function of time T(s). <FIG> is relating to a case where the proposed method is not applied.

Injected amount of fuel Qinj is presented by a graph G1.

Nominal fuel pressure Pnom is presented by a graph G2.

Actual fuel pressure Pr is presented by a graph G3.

Herein it is illustrated that the actual fuel pressure Pr is at the same level as a desired nominal fuel pressure Pnom until fuel injection to the engine <NUM> is interrupted. The interruption of fuel injection may be caused by a process of changing gear-steps of the gearbox of the vehicle. Hereby the actual fuel pressure Pr is reduced according to control routines based on injected amount of fuel Qinj. At a point of time where the gear shifting process of the gearbox is completed the actual fuel pressure Pr is built up and later stabilised at a level of the nominal fuel pressure Pnom.

According to this control procedure an undesired drop of fuel pressure Pr is appearing during resuming of fuel provision after an interruption.

<FIG> schematically illustrates a diagram wherein the three parameters of <FIG> given as a function of time T(s), for comparison reasons. <FIG> is relating to a case where the proposed method is applied. Hereby values of at least one operational parameter of the combustion engine system is considered, namely the boost pressure Pb and the Lambda-value λ.

Herein it is illustrated that the actual fuel pressure Pr is substantially at the same level as a desired nominal fuel pressure Pnom until fuel injection to the engine <NUM> is interrupted. The interruption of fuel injection is hereby caused by a process of changing gear-steps of the gearbox of the vehicle. Hereby the actual fuel pressure Pr is only slightly deviating from the nominal fuel pressure Pnom. Control routines are hereby based on injected amount of fuel Qinj as well as boost pressure Pb and/or the Lambda-value λ (see e.g. <FIG> and <FIG>). At a point of time where the gear shifting process of the gearbox is completed, the actual fuel pressure Pr is advantageously already at a level of the nominal fuel pressure Pnom.

According to this control procedure, where the proposed method is applied, substantially no (undesired) drop of the fuel pressure Pr is appearing during fuel provision interruption.

<FIG> schematically illustrates a flow chart of a method for operating a fuel supply pump <NUM> of a vehicle <NUM>. The vehicle <NUM> comprises a combustion engine system and a gearbox. The method comprises a method step s401. The method step s401 comprises the steps of:.

The method steps of the step s401 may be performed continuously or intermittently.

After the method step s401 the method ends/is returned.

<FIG> schematically illustrates a flow chart of an exemplified embodiment of a method for operating a fuel supply pump <NUM> of a vehicle <NUM>. According to one embodiment the method is activated upon detection of propulsion of the vehicle <NUM>.

The method may comprise a method step s410. The method step s410 comprises the step of determining a prevailing fuel pressure Pr. This may be performed by means of a fuel pressure sensor <NUM>. The step of determining a prevailing fuel pressure Pr may be performed continuously or intermittently. After the method step s410 a subsequent method step s420 may be performed.

The method step s420 may comprise the step of determining a boost pressure Pb provided by a turbo charger unit of the engine <NUM>. The turbo charger unit may also be denoted turbo arrangement. The boost pressure Pb may alternatively be denoted charge air pressure. The boost pressure Pb may be determined continuously or intermittently. The boost pressure Pb may be determined by means of the boost pressure sensor <NUM>. The method step s420 may comprise the step of determining values of at least one operational parameter of the combustion engine system, wherein the operational parameter is the boost pressure Pb. According to one example, wherein the combustion engine system does not comprise a turbo charger unit, the method step s420 is not performed. Hereby the proposed method is performed on the basis of a determined prevailing Lambda-value λ (see step s430). After the method step s420 a subsequent method step s430 may be performed.

The method step s430 may comprise the step of determining a prevailing Lambda-value λ. The Lambda-value λ may be determined continuously or intermittently. The Lambda-value λ may be determined by means of the Lambda-sensor arrangement <NUM> and the first control arrangement <NUM>. The method step s430 may comprise the step of determining values of at least one operational parameter of the combustion engine system, wherein the operational parameter is the Lambda-value λ. After the method step s430 a subsequent method step s440 may be performed.

The method step s440 may comprise the step of determining a change of injected amount of fuel Qinj to the engine <NUM>. The step of determining a change of injected amount of fuel Qinj may comprise the step of determining if a fuel provision rate is reduced. According to one example a change is determined if a fuel provision rate is reduced by at least <NUM>% from a prevailing fuel provision rate. According to one example a change is determined if a fuel provision rate is reduced by at least <NUM>% from a prevailing fuel provision rate. According to one example a change is determined if fuel provision is reduced to zero (that is, interrupted). This can be performed by means of the first control arrangement <NUM>. The method step s440 may comprise the step of determining a change of fuel provision to the combustion engine system. After the method step s440 a subsequent method step s450 may be performed.

The method step s450 may comprise the step of determining if the thus determined boost pressure Pb is unchanged, given that a change of injected amount of fuel Qinj has been determined. The thus determined boost pressure Pb is hereby maintained at a constant level over time when the injected amount of fuel Qinj is changed. The thus determined boost pressure Pb is hereby maintained at a constant level over time when the injected amount of fuel Qinj per second is significally reduced, e.g. by <NUM>% or more. If the boost pressure Pb is changed by more than to a predetermined extent, e.g. <NUM>%, <NUM>% or <NUM>%, it is determined that the boost pressure Pr is not unchanged. The step s450 may be performed by means of the first control arrangement <NUM>. After the method step s450 a subsequent method step s460 may be performed.

The method step s460 may comprise the step of determining if the thus determined Lambda-values λ are unchanged, given that a change of injected amount of fuel Qinj has been determined. The thus determined Lambda-values λ are hereby maintained at a constant level over time when the injected amount of fuel Qinj is changed. The thus determined Lambda-values λ are hereby maintained at a constant level over time when the injected amount of fuel Qinj per second is significally reduced, e.g. by <NUM>% or more. If the Lambda-values λ are changed by more than to a predetermined extent, e.g. <NUM>%, <NUM>% or <NUM>%, it is determined that the Lambda-value λ is not unchanged. The step s460 may be performed by means of the first control arrangement <NUM>. After the method step s460 a subsequent method step s470 may be performed.

The method step s470 may comprise the step of determining whether a gear-step change of the gearbox of the vehicle is at hand. This may be performed by means of the first control arrangement <NUM>.

The method step s470 may comprise the step of determining whether a gear step change of the gearbox is at hand, on the basis of the thus determined values Pb and λ of the at least one operational parameter.

The method step s470 may comprise the step of determining that a gear step change of the gearbox is at hand if the boost pressure Pb is unchanged over time.

The method step s470 may comprise the step of determining that a gear step change of the gearbox is not at hand if the boost pressure Pb is changed more than to a predetermined extent.

The method step s470 may comprise the step of determining that a gear step change of the gearbox is at hand if the Lambda-value λ is unchanged over time.

The method step s470 may comprise the step of determining s470 that a gear step change of the gearbox is not at hand if the Lambda-value λ is changed more than to a predetermined extent.

If it is determined that gear step change of the gearbox is at hand a subsequent step s480 may be performed.

If it is determined that a gear step change of the gearbox is not at hand a change of fuel supply pump speed Prpm is allowed.

The method step s480 may comprise the step of controlling operation of the fuel supply pump <NUM> so as to maintain fuel supply pump speed Prpm at a current/prevailing level. The method step s480 may comprise the step of controlling operation of the fuel supply pump <NUM> so as to maintain fuel supply pump speed Prpm. Hereby the actual fuel pressure Pr is maintained at a level of the nominal fuel pressure Pnom (see <FIG>).

In case a gear step change of the gearbox is not at hand the fuel supply pump speed Prpm may be controlled according to stored routines. Hereby operation of the feeder pump <NUM> may be controlled on the basis of the prevailing fuel pressure Pr such that the feeder pump speed Prpm is reduced accordingly if the prevailing fuel pressure Pr is reduced.

After the method step s480 the method ends/is returned.

<FIG> is a diagram of one version of a device <NUM>. The control arrangements <NUM> and <NUM> described with reference to <FIG> may in one version comprise the device <NUM>. The device <NUM> comprises a non-volatile memory <NUM>, a data processing unit <NUM> and a read/write memory <NUM>. The non-volatile memory <NUM> has a first memory element <NUM> in which a computer program, e.g. an operating system, is stored for controlling the function of the device <NUM>. The device <NUM> further comprises a bus controller, a serial communication port, I/O means, an A/D converter, a time and date input and transfer unit, an event counter and an interruption controller (not depicted). The non-volatile memory <NUM> has also a second memory element <NUM>.

The computer program P comprises routines for operating a fuel supply pump <NUM> of the vehicle <NUM>.

The computer program P may comprise routines for determining values of at least one operational parameter of the combustion engine system.

The computer program P may comprise routines for determining a change of fuel provision to the combustion engine system.

The computer program P may comprise routines for determining whether a gear step change of the gearbox is at hand, on the basis of the thus determined values of the at least one operational parameter.

The computer program P may comprise routines for, in case a gear step change of the gearbox is at hand, controlling operation of the fuel supply pump so as to maintain fuel supply pump speed Prpm.

The computer program P may comprise routines for, in case a gear step change of the gearbox is not at hand, allowing a change of fuel supply pump speed Prpm.

The computer program P may comprise routines for determining a boost pressure Pb of the combustion engine system and determining that a gear step change of the gearbox is at hand if the boost pressure Pb is unchanged over time.

The computer program P may comprise routines for determining a boost pressure Pb of the combustion engine system and determining that a gear step change of the gearbox is not at hand if the boost pressure Pb is changed more than to a predetermined extent.

The computer program P may comprise routines for determining a Lambda-value λ of the combustion engine system and determining that a gear step change of the gearbox is at hand if the Lambda-value λ is unchanged over time.

The computer program P may comprise routines for determining a Lambda-value λ of the combustion engine system and determining that a gear step change of the gearbox is not at hand if the Lambda-value λ is changed more than to a predetermined extent.

The computer program P may comprise routines for performing any one of the process steps detailed with reference to the disclosure.

The program P may be stored in an executable form or in compressed form in a memory <NUM> and/or in a read/write memory <NUM>.

Where it is stated that the data processing unit <NUM> performs a certain function, it means that it conducts a certain part of the program which is stored in the memory <NUM> or a certain part of the program which is stored in the read/write memory <NUM>.

The data processing device <NUM> can communicate with a data port <NUM> via a data bus <NUM>. The non-volatile memory <NUM> is intended for communication with the data processing unit <NUM> via a data bus <NUM>. The separate memory <NUM> is intended to communicate with the data processing unit via a data bus <NUM>. The read/write memory <NUM> is arranged to communicate with the data processing unit <NUM> via a data bus <NUM>. The links L210, L231, L241, L243, L261 and L271, for example, may be connected to the data port <NUM> (see <FIG>).

When data are received on the data port <NUM>, they are stored temporarily in the second memory element <NUM>. When input data received have been temporarily stored, the data processing unit <NUM> will be prepared to conduct code execution as described above.

Parts of the methods herein described may be conducted by the device <NUM> by means of the data processing unit <NUM> which runs the program stored in the memory <NUM> or the read/write memory <NUM>. When the device <NUM> runs the program, method steps and process steps herein described are executed.

Claim 1:
A method for operating a fuel supply pump (<NUM>) of a vehicle (<NUM>), the vehicle (<NUM>) comprising a combustion engine system (<NUM>) and a gearbox, the method comprising the steps of:
- determining (s420; s430) values (Pb; λ) of at least one operational parameter of the combustion engine system (<NUM>), wherein the at least one operational parameter is a boost pressure (Pb) of the combustion engine system (<NUM>) and/or a Lambda-value (λ) of the combustion engine system (<NUM>);
- determining (s440) a reduction of a fuel provision rate to the combustion engine system (<NUM>);
- determining (s470) whether a gear step change of the gearbox is at hand, on the basis of the thus determined values (Pb; λ) of the at least one operational parameter;
- in case a gear step change of the gearbox is at hand, controlling (s480) operation of the fuel supply pump (<NUM>) so as to maintain fuel supply pump speed (Prpm); and
- in case a gear step change of the gearbox is not at hand, allowing a change of fuel supply pump speed (Prpm).