Fuel metering for the operation of an internal combustion engine

What is claimed is: 1. A method for operating an internal combustion engine that is arranged for receiving both direct and intake manifold injections, the method comprising: using a same intake manifold injector, injecting water and fuel into the internal combustion engine as part of the intake manifold injection; wherein, after terminating an operating mode in which the water injection takes place, the fuel is metered via the intake manifold injector such that water present in a low-pressure accumulator, which is used for both the water injection and the fuel injection, is consumed. 2. The method of claim 1 , wherein a duration of an activation of the fuel injection is determined as a function of a PFI portion in a split operation and a quantity of water still present in the low-pressure accumulator when the fuel injection is performed. 3. The method of claim 1 , further comprising executing at least one of a start/stop function and a coasting function by which a stop of the internal combustion engine is prevented until the water present in the low-pressure accumulator is consumed. 4. The method of claim 1 , wherein, after terminating an operating mode in which the water injection takes place, the injection of the fuel is controlled based on a quantity of water still present in a low-pressure accumulator. 5. The method of claim 1 , further comprising: operating the internal combustion engine using the direct injection and an adjusted lambda value; connecting the intake manifold injector for the intake manifold injection; determining a resultant enrichment of an overall mixture by evaluating a lambda signal; determining at least one of a water portion and a fuel portion in a water/fuel mixture to be metered via the intake manifold injector. 6. The method of claim 1 , further comprising: operating the internal combustion engine using the direct injection and an adjusted lambda value; connecting the intake manifold injector for the intake manifold injection; comparing a lambda signal representing a resultant enrichment of an overall mixture to an enrichment value that corresponds to an intake manifold injection; and detecting that no water is present in the low-pressure accumulator when the lambda signal matches the enrichment value. 7. The method of claim 1 , further comprising, during or after activating the water injection, determining at least one of when and what extent a change in an ignition angle takes place. 8. The method of claim 7 , wherein the determination is based on at least one of a geometry of a fuel line via which the fuel is fed to the intake manifold injector, a geometry of a low-pressure accumulator via which the fuel and the water are fed to the intake manifold injector, a fluid quantity injected via the intake manifold injection, an instantaneous fuel pressure, an instantaneous position of a valve that controls respective quantities of the fuel and the water fed to the intake manifold injector, a control of a water pump that pumps the water to the intake manifold injector, and a control of a fuel pump that pumps the fuel to the intake manifold injector. 9. The method of claim 1 , further comprising detecting a knock sensor signal following an activation of the water injection and determining, based on the detected knock sensor signal, whether a sufficient quantity of water is meterable via the intake manifold injection. 10. The method of claim 1 , further comprising, during or after activating the water injection and operating the internal combustion engine in an operation in which both the intake manifold injection and the direct injection take place: temporarily increasing a portion of the fuel metered via the intake manifold injection; determining a resultant enrichment of an overall mixture of the water and fuel by evaluating a lambda signal; based on the determined resultant enrichment, determining a modification of the portion of the fuel and a portion of the water in the overall mixture to be metered via the intake manifold injection. 11. The method of claim 1 , wherein a portion of the fuel metered via the intake manifold injection is increased during or after activating the water injection and operating the internal combustion engine in a mode in which both the intake manifold injection and the direct injection occur. 12. The method of claim 11 , further comprising: using a software model, computing the respective portions of the fuel and of the water present in a rail; and based on the computed portions, determining when an increase in the fuel portion metered via the intake manifold injection is to be terminated. 13. The method of claim 1 , wherein the water injection occurs in a full-load range. 14. The method of claim 1 , wherein, in the water injection, the water is injected under low pressure. 15. The method of claim 1 , wherein, using a mixing or 3/2-way valve that is arranged in low-pressure circuits of a source of the water and of a source of the fuel, a switchover takes place between at least two of the injection of the water, the injection of the fuel, and a mix of the injection of the water and the fuel. 16. The method of claim 15 , wherein: the valve is a mixing valve; the method further comprises, based on a signal of a lambda sensor, controlling the mixing valve to form a mixture of the water and the fuel; and the injecting of the water and the fuel includes metering the mixture via the intake manifold injector. 17. The method of claim 1 , wherein a respective check valve is situated in each of a low-pressure circuit of a source of the fuel and a low-pressure circuit of a source of the water injection, upstream from at least one of (a) a shared fuel low-pressure line to which both the water and the fuel are fed and (b) respective inputs to a shared valve. 18. The method of claim 17 , further comprising controlling whether the water is guided into the intake manifold injector using a water pump and controlling whether the fuel is guided into the intake manifold injector using a low-pressure gasoline pump. 19. The method of claim 1 , wherein supply systems for metering the fuel and the water in a low-pressure range are demand-controlled. 20. A fuel metering system for an internal combustion engine, the system comprising: a direct fuel injector via which a direct fuel injection into the internal combustion engine can be performed; a water source; a fuel source; an intake manifold injector to which water is suppliable from the water source and fuel is suppliable from the fuel source for an injection of water and fuel into the internal combustion engine via the intake manifold injector; wherein, after terminating an operating mode in which the water injection takes place, the intake manifold injector is configured to meter the fuel such that water present in a low-pressure accumulator, which is used for both the water injection and the fuel injection, is consumed. 21. A control unit for operating an internal combustion engine that is arranged for receiving both direct and intake manifold injections, the control unit comprising: a processor coupled to a metering circuit and that is configured to control the metering circuit to inject water and fuel into the internal combustion engine as part of the intake manifold injection using a same intake manifold injector of the metering circuit; wherein, after terminating an operating mode in which the water injection takes place, the processor is configured to meter the fuel via the intake