Spill valve assembly for improved minimum delivery capability in fuel system

What is claimed is: 1. A fuel system for an internal combustion engine comprising: a fuel injection nozzle; a fuel pump including a plunger coupled to a tappet and structured to pressurize a fuel for injection into the internal combustion engine through the fuel injection nozzle, the fuel pump defining a low pressure space, a high pressure outlet, and a plunger cavity receiving the plunger and fluidly connected to the high pressure outlet; a spill valve assembly including a first spill valve and a second spill valve fluidly in parallel with one another between the plunger cavity and the low pressure space, and each of the first spill valve and the second spill valve being movable between an open position where the plunger cavity is fluidly connected to the low pressure space, and a closed position; a pumping control unit in control communication with the first spill valve and the second spill valve, the pumping control unit being structured to: command closing of the first spill valve; command closing of the second spill valve after the closing of the first spill valve to adjust the spill valve assembly to a start-of-pressurization configuration; command opening of the first spill valve while the second spill valve remains closed to adjust the spill valve assembly from the start-of-pressurization configuration to a start of spill configuration; and determine a pumping duration of the fuel pump based on a timing of the commanded closing of the second spill valve and a timing of the commanded opening of the first spill valve. 2. The fuel system of claim 1 wherein the pumping control unit is further structured to: command the closing of the first spill valve by supplying a first control current to a first electrical actuator coupled with the first spill valve; and command the closing of the second spill valve by supplying a second control current to a second electrical actuator coupled with the second spill valve, and wherein the first control current and the second control current are overlapping in time but not coincident. 3. The fuel system of claim 1 further comprising a gaseous fuel supply, and a gaseous fuel admission valve structured to admit a metered amount of a gaseous fuel for combustion in the internal combustion engine. 4. The fuel system of claim 3 wherein the pumping control unit is further structured to vary the pumping duration of the fuel pump based on the metered amount of the gaseous fuel. 5. The fuel system of claim 1 wherein the spill valve assembly meters an output of the fuel pump to a pressurized fuel reservoir. 6. The fuel system of claim 5 wherein the pressurized fuel reservoir is located fluidly between the fuel pump and the fuel injection nozzle. 7. The fuel system of claim 6 wherein the fuel injection nozzle includes a direct operated nozzle check, and is one of a plurality of fuel injection nozzles each fluidly connected to the pressurized fuel reservoir. 8. The fuel system of claim 1 wherein the fuel pump further defines a low pressure inlet, and the first spill valve and the second spill valve are arranged fluidly in parallel with one another between the plunger cavity and the low pressure inlet. 9. The fuel system of claim 8 wherein the fuel injection nozzle includes a direct operated nozzle check, and a high pressure nozzle supply passage directly fluidly connected to the high pressure outlet of the fuel pump. 10. A fuel system for an internal combustion engine comprising: a fuel supply; a plurality of fuel injection nozzles; a cam; a fuel pump including a plunger coupled to a tappet in contact with the cam and structured to pressurize a fuel for injection into the internal combustion engine through at least one of the plurality of fuel injection nozzles, the fuel pump defining a low pressure space, a high pressure outlet, and a plunger cavity receiving the plunger and fluidly connected to the high pressure outlet; a spill valve assembly including a first spill valve and a second spill valve arranged fluidly in parallel with one another between the plunger cavity and the low pressure space; and the spill valve assembly having a first configuration where each of the first spill valve and the second spill valve is open, and being adjustable to a start-of-pressurization configuration where each of the first spill valve and the second spill valve is closed, and to a start of spill configuration where the first spill valve is open and the second spill valve remains closed. 11. The fuel system of claim 10 wherein the spill valve assembly meters an output of the fuel pump. 12. The fuel system of claim 11 further comprising a pressurized fuel reservoir fluidly connected to the high pressure outlet and located fluidly between the fuel pump and the plurality of fuel injection nozzles. 13. The fuel system of claim 10 wherein the spill valve assembly further defines a low pressure inlet, and the first spill valve and the second spill valve are arranged fluidly in parallel with one another between the low pressure inlet and the plunger cavity. 14. The fuel system of claim 12 wherein one of the plurality of fuel injection nozzles includes a direct operated nozzle check, and a high pressure nozzle supply passage directly fluidly connected to the high pressure outlet of the fuel pump. 15. The fuel system of claim 13 wherein the fuel pump and one of the plurality of fuel injection nozzles are resident in a fuel injector. 16. The fuel system of claim 13 wherein the fuel supply includes a liquid fuel supply, and further comprising a gaseous fuel supply and a gaseous fuel admission valve. 17. A method of operating a fuel system for an internal combustion engine comprising: spilling fuel from a plunger cavity in a fuel pump through each of a first spill valve and a second spill valve in a spill valve assembly to a low pressure space, during moving a plunger in the fuel pump between a retracted position and an advanced position; closing the first spill valve in the spill valve assembly; closing a second spill valve in the spill valve assembly after the closing of the first spill valve to start pressurization of fuel within the plunger cavity; conveying pressurized fuel from the plunger cavity to a high pressure outlet of the fuel pump; opening the first spill valve while the second spill valve remains closed to end pressurization of fuel within the plunger cavity at a timing determining a pumping duration of the fuel pump; and feeding the pressurized fuel from the high pressure passage to a nozzle supply passage in a fuel injection nozzle. 18. The method of claim 17 wherein: the closing of the first spill valve includes closing the first spill valve in response to supplying a first electrical current to a first electrical actuator; the closing of the second spill valve includes closing the second spill valve in response to supplying a second electrical current to a second electrical actuator; and the first electrical current and the second electrical current are overlapping in time but not coincident. 19. The method of claim 17 further comprising varying the pumping duration of the fuel pump at least in part by varying a time between the closing of the first spill valve and at least one of the closing of the second spill valve or the opening of the first spill valve. 20. The method of claim 19 further comprising: injecting the pressurized fuel fed to the nozzle supply passage into a cylinder in the internal combustion engine in an injection amount that is based o