Direct injection fuel system with controlled accumulator energy storage and delivery

What is claimed is: 1. A direct injection (DI) fuel supply system for an engine of a vehicle, the DI fuel supply system comprising: a fuel rail in fluid communication with a high pressure fuel line and configured to house pressurized fuel; a fuel injector configured to inject at least a portion of the pressurized fuel housed in the fuel rail into the engine; a DI positive displacement fuel pump driven by a crankshaft of the engine, the DI positive displacement fuel pump in fluid communication with and configured to supply the pressurized fuel to the high pressure fuel line; an accumulator fluidly coupled to the high pressure fuel line at a position between the fuel rail and the fuel pump, the accumulator configured to house the pressurized fuel; an accumulator valve positioned in the high pressure fuel line at a location between the accumulator and the fuel rail, the accumulator valve configured to: variably open to regulate the flow of the pressurized fuel from both the DI fuel pump and the accumulator to the fuel rail, and close to insulate the fuel rail and the fuel injector from both (i) high fuel pressure during recharging of the accumulator and (ii) fuel pressure pulsations generated by the DI fuel pump during recharging of the accumulator; and a controller configured to: detect whether the accumulator is charged, estimate the portion of the pressurized fuel that the fuel injector will inject during a fuel injection event, when the accumulator is charged, disable the fuel pump and control opening of the accumulator valve proximate the fuel injection event such that the accumulator supplies the fuel rail with approximately the estimated portion of the pressurized fuel injected during the fuel injection event, and when the accumulator is not charged, close the accumulator valve and control the fuel pump to recharge the accumulator. 2. The DI fuel supply system of claim 1 , further comprising a piezo device configured to generate cancellation fuel pressure pulsations in the DI fuel supply system, wherein the controller is configured to control the piezo device to generate the cancellation fuel pressure pulsations to cancel at least a portion of the fuel pressure pulsations generated by the DI positive displacement fuel pump. 3. The DI fuel supply system of claim 1 , wherein the controller is configured to control the accumulator valve based further on at least one of: (i) a static flow rate of the accumulator valve; (ii) a timing of the fuel injection event; (iii) a desired pressure of the pressurized fuel in the fuel rail; and (iv) a pressure differential between a pressure of the pressurized fuel in the accumulator and a pressure of the pressurized fuel in the fuel rail. 4. The DI fuel supply system of claim 3 , further comprising a fuel rail pressure sensor configured to measure a pressure of the pressurized fuel in the fuel rail, wherein the controller is configured to utilize measurements from the fuel rail pressure sensor in detecting whether the accumulator is charged and in controlling the opening of the accumulator valve. 5. The DI fuel supply system of claim 3 , further comprising an accumulator pressure sensor configured to measure a pressure of the pressurized fuel in the accumulator, wherein the controller is configured to utilize measurements from the accumulator pressure sensor in detecting whether the accumulator is charged and in controlling the opening of the accumulator valve. 6. The DI fuel supply system of claim 5 , wherein the controller is further configured to control charging of the accumulator by the DI positive displacement fuel pump based on the measurements from the accumulator pressure sensor. 7. The DI fuel supply system of claim 6 , wherein the controller is configured to enable charging of the accumulator by the DI fuel pump when the measured accumulator pressure is less than a low pressure threshold, and wherein the controller is configured to disable charging of the accumulator by the DI fuel pump when the measured accumulator pressure is greater than a high pressure threshold that is greater than the low pressure threshold. 8. A method of operating a direct injection (DI) fuel supply system of a vehicle, the DI fuel supply system having a high pressure fuel line fluidly coupled to a fuel rail in fluid communication with a fuel injector, the method comprising: determining, at a controller of the DI fuel supply system, an estimated amount of a pressurized fuel from the fuel rail to be injected by the fuel injector during a fuel injection event, the DI fuel supply system including an accumulator valve in the high pressure fuel line positioned upstream of the fuel rail and downstream of an accumulator fluidly coupled to the high pressure fuel line, the accumulator valve being configured to close to insulate the fuel rail and the fuel injector from both (i) high fuel pressure during recharging of the accumulator and (ii) fuel pressure pulsations generated by the DI fuel pump during recharging of the accumulator; detecting, by the controller, whether the accumulator is charged; when the accumulator is charged: disabling, by the controller, a DI positive displacement fuel pump of the DI fuel supply system, and controlling, by the controller, opening of the accumulator valve during the fuel injection event such that the accumulator supplies the fuel rail with approximately the estimated portion of the pressurized fuel injected during the fuel injection event; and when the accumulator is not charged, controlling, by the controller, recharging of the accumulator by: commanding the accumulator valve closed; and commanding the fuel pump to supply the pressurized fuel to the accumulator. 9. The method of claim 8 , further comprising controlling, by the controller, a piezo device of the DI fuel supply system to generate cancellation fuel pressure pulsations that cancel at least a portion of the fuel pressure pulsations generated by the DI positive displacement fuel pump. 10. The method of claim 8 , wherein controlling the accumulator valve during the fuel injection event is further based on at least one of: (i) a static flow rate of the accumulator valve; (ii) a timing of the fuel injection event; (iii) a desired pressure of the pressurized fuel in the fuel rail; and (iv) a pressure differential between a pressure of the pressurized fuel in the accumulator and a pressure of the pressurized fuel in the fuel rail. 11. The method of claim 10 , further comprising receiving, at the controller from a fuel rail pressure sensor, measurements of the pressure of the pressurized fuel in the fuel rail, wherein detecting whether the accumulator is charged and controlling the opening of the accumulator valve are based further on the measurements from the fuel rail pressure sensor. 12. The method of claim 11 , further comprising receiving, at the controller from an accumulator pressure sensor, measurements of the pressurized fuel in the accumulator, wherein detecting whether the accumulator is charged and controlling the opening of the accumulator valve are based further on the measurements from the accumulator pressure sensor. 13. The method of claim 12 , further comprising controlling, by the controlling, charging of the accumulator by the DI positive displacement fuel pump based on the measurements from the accumulator pressure sensor. 14. The method of claim 13 , wherein controlling charging of the accumulator by the DI fuel pump includes: enabling, by the controller, charging of the accumulator by the DI positive displacement fuel pump when the measured accumulator pressure is less than a