DE102013206102A1 - System and method for water injection for an internal combustion engine - Google Patents

Abstract

A system for water injection for an internal combustion engine (12) has first injectors (16), which each inject a liquid directly into a combustion chamber (14) of the internal combustion engine (12), and second injectors (24), which each inject a liquid into an intake manifold (20 ) in front of the combustion chamber (14). At least one fuel supply valve (40) arranged between a fuel tank (38) and the first and second injectors (24) and one water supply valve (52) arranged between a water reservoir (48) and the first injectors (16) are provided. The valves (40, 52) can be switched so that the first injectors (16) are in flow connection with the fuel tank (38) as well as with the water reservoir (48) and the second injectors (24) are in flow connection with the fuel tank (38). are bringable. Water is injected into the combustion chambers (14) via the first injectors (16) only in certain load ranges. Depending on the load range, fuel is either injected directly into the combustion chambers (14) of the internal combustion engine (12) via the first injectors (16) or into the intake manifold (20) upstream of the combustion chambers (14) via second injectors (24).

Description

The invention relates to a system and a method for water injection for an internal combustion engine.

In internal combustion engines, especially in gasoline engines for passenger cars, an injection of water in addition to the actual fuel can affect the driving characteristics low, for example by a cooling effect is achieved. It has been found that a knocking combustion can be suppressed, and the efficiency of the combustion and thus the performance can be increased or the fuel consumption can be reduced.

The object of the invention is to optimize a water injection.

This is possible with a system for injecting water for an internal combustion engine having first injectors, each injecting a liquid directly into a combustion chamber of the internal combustion engine, and second injectors, each injecting a liquid into a suction pipe in front of the combustion chamber. There is provided at least one fuel supply valve disposed between a fuel tank and the first and second injectors, and a water supply valve disposed between a water reservoir and the first injectors. The fuel supply valve and the water supply valve are switchable so that the first injectors are in fluid communication with the fuel tank as well as with the water reservoir and the second injectors in fluid communication with the fuel tank can be brought. In this way, in certain load ranges or operating states of the internal combustion engine, water can be provided for injection directly into the combustion chamber, possibly mixed with fuel. In addition, this system allows to provide the fuel supply in two ways, regardless of the water injection, namely on the one direct injection by the first injectors directly into the combustion chamber and the other via a port injection before the combustion chamber, wherein the fuel mixes with the introduced air. The system according to the invention thus makes it possible to optimize the performance and the fuel consumption over the entire working range of the internal combustion engine.

When fuel is injected via the second injectors and water is injected via the first injectors, the injection timing of the water injection may be varied and shifted with respect to the time of fuel injection.

The first injectors are preferably preceded by a high-pressure pump which can be brought into fluid communication with the fuel tank via the fuel supply valve and via the water supply valve with the water reservoir. The high-pressure pump advantageously corresponds to the usual high-pressure fuel pump of a direct-injection system, which is used to generate the necessary injection pressure for the first injectors. Water and fuel may be mixed before or in the pump and the mixture injected. It is also possible, if no fuel is to be supplied via the first injectors, only to promote water with the high-pressure pump.

The water supply valve is preferably a metering valve, via which the water injection is freely adjustable up to a predetermined maximum flow. In this way one gains another variable parameter that can be used to optimize combustion.

The necessary injection pressure for the second injectors can usually already be achieved by a fuel prefeed pump upstream of the high-pressure pump, which is usually part of the direct injection system.

In order to promote the water from the water reservoir, an additional water pump is preferably connected between the water reservoir and the water supply valve, which promotes water to the high pressure pump.

The fuel supply valve, the water supply valve and also the water supply pump are preferably connected by a control unit as needed, wherein the control unit can advantageously also control the second injectors. The control unit is connected, for example, to an engine electronics of the internal combustion engine or integrated into these.

In a method according to the invention for injecting water for an internal combustion engine, water is injected via the first injectors into the combustion chambers of the internal combustion engine only in certain load ranges or operating modes of the internal combustion engine and fuel depends on the load range or operating mode either directly via the first injectors in the combustion chambers of the internal combustion engine or injected via the second injectors in the suction tube, more precisely in a Saugrohrabschnitt directly upstream of the combustion chambers. This method can be realized well with a system as described above.

The fuel injection is preferably carried out either exclusively in the combustion chamber or only in the suction pipe section, but not in both areas at the same time. The water injection, however, preferably always takes place only in the combustion chamber and not in the Saugrohrabschnitt, but it can be suspended depending on the load range of the internal combustion engine or its operating mode.

For example, no water can be injected in a first load range or operating mode of the internal combustion engine, and fuel can be injected into the combustion chambers exclusively via the first injectors. This mode of operation is approximately favorable in the case of a cold start of the internal combustion engine or in the regeneration of a catalytic converter, ie in cases where heating of the internal combustion engine or generation of a high exhaust gas temperature is desired.

In a second load range, which is in particular in a medium speed range below the full load, preferably no water is injected, and fuel is injected exclusively via the second injectors in the respective Saugrohrabschnitt. Depending on the internal combustion engine, this second load range may, for example, be below 4,000 l / min and below approximately 200 Nm (or below 100 Nm / l of displacement).

In a third load range, which is in particular in a medium speed range substantially at full load, however, preferably water is injected via the first injectors into the combustion chambers and fuel injected exclusively via the second injectors in the Saugrohrabschnitt. This third load range, for example, at less than 4,000 l / min and from about 200 Nm (or from about 100 Nm / liter displacement) are. In this area, the cooling effect is desired by injected water and provides z. B. for an increase in performance of the internal combustion engine. The timing of the water injection may be offset from the timing of the fuel injection in the duty cycle of the internal combustion engine.

In a fourth load range, which is in particular in a high speed range substantially at full load, water and fuel can be injected via the first injectors in the combustion chambers. This fourth load range may, for example, be above 4,000 l / min and above approximately 150 Nm (or approximately 75 Nm / liter displacement).

The numerical values mentioned are naturally dependent on the respective engine and can vary from internal combustion engine to internal combustion engine. In principle, the water injection at high speeds and high load ranges, where a cooling effect is advantageous.

The invention will be described in more detail below with reference to an embodiment with reference to the accompanying drawings. In the drawings show:

1 a schematic hydraulic and electronic circuit diagram of a system according to the invention for water injection; and

2 a schematic representation of the injection of water and fuel in different load ranges according to a method for water injection according to the invention.

1 schematically shows a system 10 for water injection for an internal combustion engine 12 in which the internal combustion engine 12 In addition to conventional fuel, water or a mixture of water with other liquids can be supplied. In this example, the internal combustion engine 12 an Otto engine and the fuel is gasoline.

Normally, the amount of water injected is less than the amount of fuel injected.

The internal combustion engine 12 has several combustion chambers 14 on, in each of which an unillustrated piston is moved to generate the drive energy. Each of the combustion chambers 14 is in direct flow communication with a first injector 16 , the liquid coming from a high-pressure pump 18 is delivered to the combustion chamber 14 injects. The high pressure pump 18 generates, for example, a pressure of 200 to 250 bar.

The combustion chambers 14 is also used to burn the fuel through a suction pipe 20 fed to a gas mixture, wherein a separate Saugrohrabschnitt 22 to each of the combustion chambers 14 leads. At each of the suction pipe sections 22 is another, second injector 24 arranged, which is a liquid in the Saugrohrabschnitt 22 in front of the combustion chamber 14 can inject.

At the in 1 illustrated system 10 is the internal combustion engine 12 equipped with a turbocharger so that compressed air, optionally mixed with recirculated exhaust gas, into the intake manifold 20 is introduced. The compressed charge air is in a charge air cooler 26 cooled, a compressor 28 is downstream in terms of flow. The compressor 28 is from a turbine 30 in the exhaust system 32 driven. The charge air flow is in a known manner by an air mass meter 34 controlled.

In the exhaust system 32 Here are one or more exhaust treatment plants 36 provided, for example, conventional catalysts or Particulate filter, which absorb pollutants from the exhaust gas.

The fuel becomes the high-pressure pump 18 or the second injectors 24 from a fuel tank 38 fed. One with the fuel tank 38 Connected fuel line branches into a fuel line 44 leading to the second injectors 24 leads, and a fuel line 46 leading to the high pressure pump 18 and to the first injectors 16 leads. A valve 40 that in the fuel line 46 upstream of the high pressure pump 18 is arranged, allows a shutdown of the fuel flow to the first injectors 16 ,

The injection pressure for the second injectors 24 is here alone on a fuel feed pump 42 generates the fuel from the fuel tank 38 also to the high pressure pump 18 promotes.

Injection via the second injectors 24 is through valves of the injectors 24 controlled. It would also be possible in the fuel line 44 from the fuel tank 38 to the second injectors 24 to insert another valve or the valve 40 to the junction of the fuel lines 44 . 46 to place and form it, for example, as a 3/2-way valve to a fuel flow either to the high-pressure pump 18 or to the second injectors 24 to release or close.

A water storage tank 48 is via a water pump 50 and a water supply valve 52 in a water supply 54 with the high pressure pump 18 connected. The water supply valve 52 is designed as a metering valve, so that the water flow to the high pressure pump 18 and about the injected amount of water can be varied. The necessary prefeed pressure can be adjusted via the water feed pump 50 set, this can be z. B. generate a pressure of about 1 to 10 bar. The water storage tank 48 For example, it has a volume of 8 to 10 liters.

The control of the second injectors 24 , optional of the first injectors 16 , the fuel supply valve 40 , the water supply valve 52 and the water pump 50 is here by a control unit 56 taken over the control lines 58 can communicate with these components (in the 1 For reasons of clarity, only one of the lines is provided with a reference numeral).

The control unit 56 also receives information from a pressure sensor 60 , the upstream of the water supply valve 52 in the water supply 54 is arranged, as well as from a temperature sensor 62 The temperature of the water in the water reservoir 48 measures. A level gauge 64 monitors the level of water in the water reservoir 48 and also reports this to the control unit 56 ,

The inlet of the water supply 54 is here through a filter 66 protected, which filters out contaminants from the water.

Optional is a heater 68 for heating the water in the water storage tank 48 provided to prevent it from freezing at low ambient temperatures or thaw at low ambient temperatures when starting the vehicle. The heating is also via the control unit 56 controlled.

The system 10 can be switched so that fuel optionally through the first injectors 16 with high pressure directly into the combustion chambers 14 or alternatively under low pressure via the second injectors 24 into the suction pipe sections 22 is injected and from there with the combustion chambers 14 supplied air flow into the combustion chambers 14 arrives.

In this example, fuel is either through the first injectors 16 or over the second injectors 24 fed. The choice of fuel injection is, as will be described below, depending on the load range or operating mode in which the internal combustion engine 12 just working.

About the water supply 54 can water over the first injectors 16 directly into the combustion chambers 14 be injected with injected fuel. The mixing takes place here directly in the high pressure pump 18 or in a supply line directly upstream of the high pressure pump 18 , The wiring is designed in such a way that water is also delivered to the high-pressure pump 18 when the fuel supply valve 40 is closed and the fuel exclusively through the second injectors 24 into the suction pipe sections 22 is injected. In this case it is also possible to choose the timing of the water injection so that it does not coincide with the fuel injection.

The water injection is switched on only in certain load ranges, in which a performance improvement by the water supply can be achieved. In addition, the water supply is turned off when the level gauge 64 too low or the temperature sensor 62 too low a temperature in the water reservoir 48 which is at risk of freezing.

In 2 is shown as about the system 10 the water and fuel injection in different load ranges of the internal combustion engine 12 can be varied.

By way of example, four load ranges or operating modes are given. The details of the individual load ranges are, of course, variable at the discretion of the skilled person.

Injection via the first injectors 16 is marked with a "B", injection via the second injectors 24 with an "S".

In a first load range or operating mode I, which corresponds to a cold start of the internal combustion engine, but also alternatively during operation of the motor vehicle a state in which a regeneration of the exhaust gas treatment plants 36 is to be made, the fuel is exclusively through the first injectors 16 in the combustion chambers 14 injected. There is no water discharge. In these modes of operation is a rapid heating of the internal combustion engine 12 or a high exhaust gas temperature desired.

In a second load range II, which in a medium speed range and at a torque below the full load of the internal combustion engine 12 lies (in the example of the 2 below about 4,000 l / min and below about 200 Nm), there is also no water injection, but the fuel is completely through the second injectors 24 into the suction pipe sections 22 in front of the combustion chambers 14 injected. The fuel supply valve 40 in the fuel line 44 is closed. The high pressure pump 18 can be switched off in this case.

In a third load range III, which is also in a medium speed range, but at a higher load, especially at full load (in the example of 2 below about 4,000 l / min and at torques of above about 200 Nm), the fuel injection continues to take place exclusively via the second injectors 24 into the suction pipe sections 22 in front of the combustion chamber 14 but at the same time it gets water through the first injectors 16 in the combustion chambers 14 injected. Water is now through the water pump 50 , the water supply valve 52 and the high pressure pump 18 from the water storage tank 48 to the first injectors 16 promoted and with high injection pressure in the combustion chambers 14 injected. There it can develop a cooling effect and so the combustion in the combustion chambers 14 influence positively.

Finally, in a fourth load range IV, which here is at high speed and preferably also at full load (above about 4,000 l / min and at torques above about 150 Nm), finally, the water injection via the first injectors 16 however, the fuel injection changes from the second injectors 24 on the first injectors 16 , Fuel and water are in or before the high pressure pump 18 mixed. The amount of water to be injected is controlled by the flow through the water supply valve 52 through the control unit 56 established. The mixture of water and fuel is via the first injectors 16 in the combustion chambers 14 injected.

The amount of water to be injected can, for. B. within the load ranges are still varied within a certain limits in order to optimally adjust the combustion process.

Claims (10)

Water injection system for an internal combustion engine ( 12 ) with first injectors ( 16 ), each containing a liquid directly into a combustion chamber ( 14 ) of the internal combustion engine ( 12 ) and with second injectors ( 24 ), each containing a liquid in a suction tube ( 20 ) in front of the combustion chamber ( 14 ), with at least one between a fuel tank ( 38 ) and the first and second injectors ( 24 ) arranged fuel supply valve ( 40 ) and one between a water reservoir ( 48 ) and the first injectors ( 16 ) arranged water supply valve ( 52 ), wherein the fuel supply valve ( 40 ) and the water supply valve ( 52 ) are switchable so that the first injectors ( 16 ) in fluid communication with the fuel tank ( 38 ) as well as with the water reservoir ( 48 ) are bring bar and the second injectors ( 24 ) in fluid communication with the fuel tank ( 38 ) bring bar are. System according to claim 1, characterized in that the first injectors ( 16 ) a high pressure pump ( 18 ) which is connected via the fuel supply valve ( 40 ) with the fuel tank ( 38 ) and via the water supply valve ( 52 ) with the water reservoir ( 48 ) can be brought into fluid communication. System according to claim 2, characterized in that the water supply valve ( 52 ) is a metering valve, via which the water injection is freely adjustable up to a predetermined maximum flow. System according to one of the preceding claims, characterized in that one of the high-pressure pump ( 18 ) upstream fuel prefeed pump ( 42 ) is provided, the injection pressure for the second injectors ( 24 ) generated. System according to one of the preceding claims, characterized in that a water pump ( 50 ) between the water reservoir ( 48 ) and the water supply valve ( 52 ), the water to the high pressure pump ( 18 ) promotes. Method for water injection for an internal combustion engine, in particular for operating a system according to one of the preceding claims, in which only in certain load ranges of the internal combustion engine ( 12 ) Water via first injectors ( 16 ) in combustion chambers ( 14 ) of the internal combustion engine ( 12 ) and fuel depending on the load range either via the first injectors ( 16 ) directly into the combustion chambers ( 14 ) of the internal combustion engine ( 12 ) or via second injectors ( 24 ) in a suction tube ( 20 ) upstream of the combustion chambers ( 14 ) is injected. A method according to claim 6, characterized in that in a first load range, in particular at the start of the internal combustion engine ( 12 ) no water is injected and only through the first injectors ( 16 ) into the combustion chambers ( 14 ) is injected. Method according to one of claims 6 and 7, characterized in that in a second load range, which is in particular in a medium speed range below the full load, no water is injected and fuel exclusively through the second injectors ( 24 ) in the suction pipe ( 20 ) is injected. Method according to one of claims 6 to 8, characterized in that in a third load range, which is in particular in a medium speed range substantially at full load, water over the first injectors ( 16 ) into the combustion chambers ( 14 ) and fuel exclusively via the second injectors ( 24 ) in the suction pipe ( 20 ) is injected. Method according to one of claims 7 to 10, characterized in that in a fourth load range, which is in particular in a high speed range substantially at full load, water and fuel through the first injectors ( 16 ) into the combustion chambers ( 14 ) are injected.

Images