DE102013215958B4 - Method and device for operating a high-pressure fuel pump and system - Google Patents

Abstract

A high-pressure fuel pump (5) of a high-pressure fuel accumulator (7) of a vehicle is operated free of a predetermined engine speed and free of a predetermined fuel demand depending on a given efficiency range of the high-pressure fuel pump (5) for storing a hydraulic energy by means of the fuel in the high-pressure fuel accumulator (7).

Description

On the one hand, the invention relates to a method for operating a high-pressure fuel pump and, on the other hand, to a corresponding device for operating the high-pressure fuel pump and a corresponding system comprising the device.

Vehicles often have a high-pressure fuel storage and a high-pressure fuel pump. The high-pressure fuel storage, the so-called common rail, serves to store a fuel volume in order to enable multiple injections with a largely constant pressure.

JP H11 050 933 A discloses a pressure accumulator fuel injection system wherein high pressure fuel is provided by a high pressure pump, wherein the high pressure pump is driven by an electric drive oriented solely on the efficiency of the high pressure pump.

In DE 10 2008 050 051 A1 a method for stopping an internal combustion engine of a motor vehicle is described, wherein a high-pressure fuel storage uses as hydraulic accumulator energy that is released when stopping the internal combustion engine to restart the internal combustion engine.

DE 10 2009 025 359 A1 discloses a hybrid vehicle having an internal combustion engine and a hydraulic pressure accumulator, which is chargeable by a pumping hydraulic machine by conveying pressure fluid from a liquid storage, and which serves in an acceleration process as a pressure medium source for a working as a motor hydraulic machine, wherein fuel as hydraulic Medium is used in a separate storage circuit.

The object on which the invention is based is, on the one hand, to provide a method and, on the other hand, a device for operating a high-pressure fuel pump of a high-pressure fuel accumulator which contributes to simply storing a hydraulic energy in the high-pressure fuel accumulator.

The object is solved by the features of the independent claims. Advantageous embodiments of the invention are characterized in the subclaims.

The invention is characterized on the one hand by a method for operating a high-pressure fuel pump of a high-pressure fuel accumulator of a vehicle and on the other hand by a corresponding device for operating the high-pressure fuel pump and a corresponding system having the device, and the high-pressure fuel pump and the high-pressure fuel storage. The high-pressure fuel pump is operated free of a predetermined engine speed and free of a predetermined fuel demand depending on a predetermined efficiency range of the high-pressure fuel pump for storing a hydraulic energy by means of the fuel in the high-pressure fuel storage.

The predetermined efficiency range is, for example, an area in which the high-pressure fuel pump has a very high efficiency, that is, for example, an efficiency of more than 50%. The efficiency depends in this case, for example, on a flow rate and / or from a prevailing in the high-pressure fuel storage fluid pressure and / or a fluid pressure in an inlet to the high-pressure fuel pump and thus, for example, by measuring the flow rate and / or the fluid pressure in the high-pressure fuel storage and / or fluid pressure to be checked in the inflow.

As a result, the high-pressure fuel pump can be operated according to the invention, only if it operates very efficiently. The high-pressure fuel pump is not operated depending on the engine speed and not dependent on a given fuel demand. Thus, it is possible to operate the high-pressure fuel pump always in a very high efficiency range. Thus, a hydraulic energy can be stored in the high-pressure fuel storage in a simple manner, regardless of the engine speed and independent of a fuel demand, which can be used later for injection operations, for example. However, it can also be used alternatively or additionally for other consumers.

To store a lot of hydraulic energy, for example, it is advantageous to use a larger, compared to a conventional high-pressure accumulator, high-pressure fuel storage, so for example, a high-pressure fuel storage having a volume of at least 40 cm ³ .

According to an advantageous embodiment, the high-pressure fuel pump is operated by means of a recuperated energy.

For example, the high-pressure fuel pump is operated by means of a recuperated energy, if this recuperated energy otherwise can not be used, for example because the vehicle has no designated electrical energy storage and / or because a designated electrical energy storage is already fully charged. This allows recuperated energy to be used to convert it into hydraulic energy and store it. As a result, a very high energy efficiency of the vehicle can be achieved.

According to a further advantageous embodiment, the recuperated energy comprises an energy generated by means of brake energy recuperation.

Just by Bremsenergierekuperation can be easily gain energy. For example, for this purpose, the mechanical energy generated in the braking energy is converted by means of a generator into electrical energy and stored by means of the high-pressure fuel pump in the form of hydraulic energy in the high-pressure fuel tank.

According to a further advantageous embodiment, the recuperated energy comprises an energy generated by means of exhaust heat recuperation.

By means of an exhaust heat recuperation it is easy to gain energy. For example, for this purpose, the exhaust heat is converted by means of thermodynamic cycle through a turbine into mechanical energy and from there, for example by means of a generator into electrical energy and stored by means of the high-pressure fuel pump in the form of hydraulic energy in the high-pressure fuel tank.

According to a further advantageous refinement, the high-pressure fuel accumulator additionally has a pressure tank for storing the hydraulic energy.

Thus it is possible to store a lot of hydraulic energy. The pressure tank is for example a diaphragm accumulator. The pressure tank has, for example, a volume of at least one liter.

According to a further advantageous embodiment, the high-pressure fuel pump with an electric machine is mechanically coupled to operate the high-pressure fuel pump.

As a result, the high-pressure fuel pump can be operated very easily by means of electrical energy. This also makes it very easy to operate the high-pressure fuel pump by means of a recuperated electrical energy, such as by means of a recuperated braking energy and / or a recuperated exhaust heat energy.

According to a further advantageous embodiment, the high-pressure fuel pump is designed as a hydraulic machine that can be operated as a high-pressure fuel pump or as a hydraulic motor. The high-pressure fuel pump is mechanically coupled to an electric machine for driving the electric machine by means of the hydraulic energy stored in the high-pressure fuel accumulator. The high-pressure fuel pump is operated as a hydraulic motor depending on an energy requirement.

As a result, the energy stored hydraulically can easily be converted into electrical energy in an energy request by the high-pressure fuel pump is operated as a hydraulic motor and hereby the electric machine is operated as a generator. Thus, it is possible to use the stored hydraulic energy not only for injections in an internal combustion engine, but also, for example, for electrical consumers in the vehicle and / or for charging an electrical energy storage.

According to a further advantageous embodiment, the stored by means of the fuel in the high-pressure fuel accumulator hydraulic energy is provided for operating an internal combustion engine free of immediate Nachförderung or in particular free of Nachförderung of fuel by means of the high-pressure fuel pump. For example, if the high-pressure fuel pump is driven mechanically by the internal combustion engine, the high-pressure fuel pump can be decoupled from the internal combustion engine by means of a mechanical and / or hydraulic and / or magnetic clutch, so that injectors of the internal combustion engine are supplied solely from the high-pressure fuel accumulator and / or the pressure tank can. As a result, for example, drag losses can be saved on the high-pressure fuel pump.

Embodiments of the invention are explained in more detail below with reference to the schematic drawings.

Show it:

1 a system with a high-pressure fuel pump and

2 a flowchart for operating the high-pressure fuel pump.

1 shows a system 1 , The system 1 has a high-pressure fuel pump 5 of a vehicle.

The high-pressure fuel pump 5 For example, gasoline is designed to produce pressures up to 200 bar and diesel pressures up to 2500 bar.

The high-pressure fuel pump 5 is with a high-pressure fuel storage 7 connected to the so-called common rail. On one inlet side is the high-pressure fuel pump 5 for example via a filter 15 with a fuel tank 10 connected.

In addition, the high-pressure fuel pump 5 for example, with an electric machine 17 mechanically coupled. The electric machine 17 is designed for example as an electric motor. In this way, the high-pressure fuel pump 5 from the electric machine 17 are driven.

The high-pressure fuel pump 5 is designed for example as a hydraulic machine that can be operated both as a high-pressure fuel pump or as a hydraulic motor. In this case, the electric machine 17 alternatively or additionally designed as a generator. So can the high-pressure fuel pump 5 the electric machine 17 as a hydraulic motor, for converting hydraulic energy into electrical energy.

The high-pressure fuel storage 7 For example, it also has a pressure tank 9 on to store hydraulic energy. The pressure tank 9 is for example a membrane memory. The pressure tank 9 has, for example, a pressure volume of at least one liter.

The high-pressure fuel storage 7 is additionally with several injectors 20 connected to operate an internal combustion engine of the vehicle.

To operate the high-pressure fuel pump 5 is the high-pressure fuel pump 5 with a control device 30 connected. The control device 30 may also be referred to as a device for operating a high-pressure fuel pump. The control device 30 includes an arithmetic unit, a program and data memory and at least one interface with which they communicate with the high-pressure fuel pump 5 coupled to control the high-pressure fuel pump 5 , Furthermore, the control device 30 with the electric machine 17 be connected to control the electric machine 17 , The arithmetic unit and / or the program and data memory can be formed into one unit and / or distributed over several units.

To operate the high-pressure fuel pump 5 is in the program and data memory of the control device 30 preferably stores a program that can be processed during operation of the vehicle. The program is described below with reference to the flowchart of 2 explained in more detail.

The program is started in a step S1 in which variables can be initialized if necessary.

In a step S3, it is determined in what efficiency W the high-pressure fuel pump 5 is currently being operated. This happens, for example, taking into account a fluid pressure on an input side of the high-pressure fuel pump 5 and / or the fluid pressure in the high-pressure fuel storage 7 and / or a delivery rate of fluid.

In a step S5 it is checked whether the determined efficiency W lies within a predetermined efficiency range. The predetermined efficiency range is, for example, an area in which the high-pressure fuel pump 5 a very high efficiency W, that is, for example, has an efficiency W over 50%. If the efficiency W is not in the efficiency range, the program is continued in a step S7. If it is within the efficiency range, the program is continued in a step S9.

In step S7, the high-pressure fuel pump 5 free of a predetermined engine speed and free of a predetermined fuel demand in the given efficiency range of the high-pressure fuel pump 5 operated to store a hydraulic energy by means of the fuel in the high-pressure fuel storage 7 and / or in the pressure tank 9 , For this purpose, for example, the flow rate of the high-pressure fuel pump 5 increased, for example, by an inlet valve of the high-pressure fuel pump 5 earlier, or temporally closer to a bottom dead center of a pump piston of the high-pressure fuel pump 5 is closed. Thus, hydraulic energy in the high-pressure fuel storage 7 and / or in the pressure tank 9 get saved.

For example, the high-pressure fuel pump 5 operated in step S7 by means of a recuperated energy, such as a recuperated braking energy and / or a recuperated exhaust gas heat energy. For example, the high-pressure fuel pump 5 operated by the recuperated energy when this recuperated energy can not be used otherwise, for example, because the vehicle has no designated electrical energy storage and / or because a designated electrical energy storage is already fully charged.

In a subsequent step S9 it is checked whether an energy requirement E is present. If there is an energy requirement E, the program is continued in a step S11. If there is no energy request E, the program is continued in step S3.

In step S11, the high-pressure fuel pump 5 depending on the energy requirement E operated as a hydraulic motor for driving the electric machine 17 as a generator and thus to convert the hydraulic energy into electrical energy. The high-pressure fuel pump 5 For example, it is operated as a hydraulic motor until there is no more energy demand E and / or until a predetermined lower pressure limit in the high-pressure fuel accumulator 7 is reached. For example, the electrical energy generated thereby can be used for electrical consumers in the vehicle and / or for charging an electrical energy store.

Subsequently, the program is continued in step S3.

The two functions of the high-pressure fuel pump 5 , So operating as a high-pressure pump and operating as a hydraulic motor can also be implemented in two separate programs, in which case it must be ensured that not both functions can be performed simultaneously.

Alternatively, or in addition to the conversion of hydraulic energy into electrical energy can by means of the fuel in the high-pressure fuel storage 7 and / or in the pressure tank 9 by means of injectors 20 also an internal combustion engine of the vehicle to be operated.

In this way, the high-pressure fuel storage 7 and / or the pressure tank 9 in addition to use as high-pressure fuel storage 7 be used for operating the internal combustion engine as a hydraulic energy storage, for example, free from an immediate Nachförderung or free of Nachförderung of fuel by means of the high-pressure fuel pump 5 , whereby, for example, an energy efficiency of the vehicle can be improved.

If the high-pressure fuel pump 5 For example, is driven mechanically via the internal combustion engine, so the high-pressure fuel pump 5 For example, be decoupled by means of a mechanical and / or hydraulic and / or magnetic coupling of the internal combustion engine, so that the injectors alone from the high-pressure fuel storage 7 and / or the pressure tank 9 can be supplied. As a result, for example, drag losses on the high-pressure fuel pump 5 be saved.

LIST OF REFERENCE NUMBERS

1

system

5

High-pressure fuel pump

7

High-pressure fuel storage

9

pressure tank

10

Fuel tank

15

filter

17

electric machine

20

injector

30

control device

W

efficiency

e

energy requirement

Claims (9)

Method for operating a high-pressure fuel pump ( 5 ) of a high-pressure fuel accumulator ( 7 ) of a vehicle in which the high-pressure fuel pump ( 5 ) free of a predetermined engine speed and free of a predetermined fuel requirement depending on a predetermined range of action of the high-pressure fuel pump ( 5 ) for storing a hydraulic energy by means of the fuel in the high-pressure fuel storage ( 7 ). Method according to claim 1, wherein the high-pressure fuel pump ( 5 ) is operated by means of a recuperated energy. The method of claim 2, wherein the recuperated energy comprises energy generated by brake energy recombination. The method of claim 2 or 3, wherein the recuperated energy comprises energy generated by exhaust heat recuperation. Method according to one of the preceding claims, wherein the high-pressure fuel storage ( 7 ) additionally a pressure tank ( 9 ) for storing the hydraulic energy. Method according to one of the preceding claims, in which the high-pressure fuel pump ( 5 ) with an electric machine ( 17 ) is mechanically coupled to operate the high-pressure fuel pump ( 5 ). Method according to claim 6, wherein the high-pressure fuel pump ( 5 ) is designed as a hydraulic machine which can be operated as a high-pressure fuel pump or as a hydraulic motor and with the electric machine ( 17 ) is mechanically coupled, for driving the electric machine ( 17 ) by means of the in the high-pressure fuel storage ( 7 ) stored hydraulic energy, in which the high-pressure fuel pump ( 5 ) depending on one Energy requirement (E) is operated as a hydraulic motor. Method according to one of the preceding claims, wherein the means of the fuel in the high-pressure fuel storage ( 7 ) stored hydraulic energy is provided for the operation of an internal combustion engine free from an immediate Nachförderung of fuel by means of the high-pressure fuel pump ( 5 ). Device for operating a high-pressure fuel pump ( 5 ), wherein the device is designed to carry out a method according to one of claims 1 to 8.

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