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A fuel supply system for a reciprocating-piston engine includes a storage tank; a wall of the storage tank defining a first aperture and a second aperture therethrough; a first fuel injector fluidly coupled with the first aperture of the storage tank via a pressure control module and a first fuel in

A fuel supply system for a reciprocating-piston engine includes a storage tank; a wall of the storage tank defining a first aperture and a second aperture therethrough; a first fuel injector fluidly coupled with the first aperture of the storage tank via a pressure control module and a first fuel injector supply conduit; a pump fluidly coupled with the second aperture of the storage tank; and a second fuel injector fluidly coupled with an outlet port of the pump via a second fuel injector supply conduit. The pressure control module is configured to maintain a pressure in the first fuel injector supply conduit within a pressure range that includes a pressure value that is less than a pressure inside the storage tank. The pump is configured to maintain a pressure inside the second fuel injector supply conduit that is greater than the pressure inside the first fuel injector supply conduit.

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1. A fuel supply system for a reciprocating-piston engine, the fuel supply system comprising: a storage tank, a wall of the storage tank defining a first aperture and a second aperture therethrough, the first aperture being distinct from the second aperture;a first fuel injector fluidly coupled with

1. A fuel supply system for a reciprocating-piston engine, the fuel supply system comprising: a storage tank, a wall of the storage tank defining a first aperture and a second aperture therethrough, the first aperture being distinct from the second aperture;a first fuel injector fluidly coupled with the first aperture of the storage tank via a pressure control module and a first fuel injector supply conduit, the first fuel injector supply conduit being disposed fluidly in series between the pressure control module and first fuel injector,the pressure control module being configured to maintain a pressure in the first fuel injector supply conduit that is less than a pressure inside the storage tank;a pump fluidly coupled with the second aperture of the storage tank; anda second fuel injector fluidly coupled with an outlet port of the pump via a second fuel injector supply conduit, the pump being configured to maintain a pressure inside the second fuel injector supply conduit that is greater than the pressure inside the first fuel injector supply conduit. 2. The fuel supply system of claim 1, wherein the pressure control module includes a first check valve and a second check valve, the first check valve being configured and arranged to effect fluid communication therethrough only along a flow direction extending from the storage tank toward the first fuel injector supply conduit,the second check valve being configured and arranged to effect fluid communication therethrough only along a flow direction extending from the first fuel injector supply conduit toward the storage tank. 3. The fuel supply system of claim 2, wherein the pressure control module includes a first resilient member that biases the first check valve to allow flow therethrough only when a pressure at an inlet to the first check valve exceeds a pressure at an outlet of the first check valve by a first pressure differential, and wherein the pressure control module includes a second resilient member that biases the second check valve to allow flow therethrough only when a pressure at an inlet to the second check valve exceeds a pressure at an outlet of the second check valve by a second pressure differential. 4. The fuel supply system of claim 3, wherein the first pressure differential is greater than the second pressure differential. 5. The fuel supply system of claim 1, wherein the second fuel injector defines an outlet drain port, the outlet drain port being fluidly coupled to the first fuel injector supply conduit via a drain check valve, the drain check valve being configured and arranged to effect fluid communication between the outlet drain port and the first fuel injector supply conduit only in a flow direction that extends from the outlet drain port toward the first fuel injector supply conduit. 6. The fuel supply system of claim 1, wherein the reciprocating-piston engine includes a combustion pre-chamber and a main combustion chamber, the combustion pre-chamber being fluidly coupled to the main combustion chamber, and the first fuel injector is a pre-chamber fuel injector that is fluidly coupled to the main combustion chamber via the combustion pre-chamber. 7. The fuel supply system of claim 1, wherein the reciprocating-piston engine includes an intake manifold and a main combustion chamber, the intake manifold being fluidly coupled to the main combustion chamber, and the first fuel injector is an intake fuel injector that is fluidly coupled to the main combustion chamber via the intake manifold. 8. The fuel supply system of claim 1, wherein the storage tank is configured to contemporaneously store a liquid phase of a fuel and a gaseous phase of the fuel, the liquid phase of the fuel being separated from the gaseous phase of the fuel by a free surface defined therebetween, the first aperture of the storage tank being arranged to effect fluid communication between the first aperture and the gaseous phase of the fuel along a flow path that does not include the liquid phase of the fuel,the second aperture of the storage tank being arranged to effect fluid communication between the second aperture and the liquid phase of the fuel along a flow path that does not include the gaseous phase of the fuel. 9. An engine, comprising: a block defining a cylinder bore therethrough;a piston disposed within the cylinder bore and configured for reciprocating motion relative to the cylinder bore, the cylinder bore and the piston at least partly defining a main combustion chamber;an oxidizer intake conduit disposed in selective fluid communication with the main combustion chamber via an intake valve;an intake fuel injector having at least one outlet orifice disposed in fluid communication with the main combustion chamber via the oxidizer intake conduit;a direct fuel injector having at least one outlet orifice disposed in direct fluid communication with the main combustion chamber along a flow path that does not include the oxidizer intake conduit;a storage tank, a wall of the storage tank defining a first aperture and a second aperture therethrough,the first aperture being distinct from the second aperture, the first aperture of the storage tank being fluidly coupled to an inlet of the intake fuel injector via a pressure control module,the pressure control module being configured to maintain a pressure at the inlet of the intake fuel injector that is less than a pressure inside the storage tank; anda pump fluidly coupled with the second aperture of the storage tank, an inlet of the direct fuel injector being fluidly coupled to an outlet of the pump, the pump being configured to maintain a pressure at the inlet of the direct fuel injector that is greater than the pressure at the inlet of the intake fuel injector. 10. The engine of claim 9, further comprising a pre-chamber assembly that includes a pre-chamber body defining a pre-chamber cavity and defining at least one orifice therethrough, the pre-chamber cavity being in fluid communication with the main combustion chamber via the at least one orifice,a pre-chamber fuel injector disposed in fluid communication with the main combustion chamber via the pre-chamber cavity, andan ignition source operatively coupled to the pre-chamber cavity. 11. The engine of claim 10, further comprising an intake throttle valve disposed in the oxidizer intake conduit, and disposed fluidly in series between an inlet to the oxidizer intake conduit and the intake valve. 12. The engine of claim 10, wherein the oxidizer intake conduit does not include an intake throttle valve disposed fluidly in series between an inlet to the oxidizer intake conduit and the intake valve. 13. The engine of claim 10, further comprising a controller being operatively coupled to the direct fuel injector, the pre-chamber fuel injector, the intake fuel injector, and the pump, the controller being configured to operate the engine in a first mode when a speed of the engine is less than a predetermined threshold speed, a load of the engine is less than a predetermined threshold load, or a temperature of the engine is less than a predetermined threshold temperature, andoperate the engine in a second mode when a speed of the engine is greater than the predetermined threshold speed, the load of the engine is greater than the predetermined threshold load, or the temperature of the engine is greater than the predetermined threshold temperature,wherein according to the first mode, fuel is delivered to the pre-chamber cavity via the pre-chamber fuel injector, fuel is delivered to the oxidizer intake conduit via the intake fuel injector, and fluid communication between the direct fuel injector and the main combustion chamber is blocked, andwherein according to the second mode, fuel is delivered to the pre-chamber cavity via the pre-chamber fuel injector, and fuel is delivered to the main combustion chamber via the direct fuel injector. 14. The engine of claim 13, wherein the oxidizer intake conduit does not include an intake throttle valve disposed fluidly in series between an inlet to the oxidizer intake conduit and the intake valve, and wherein further according to the second mode, the engine is operated according to a skip-fire schedule. 15. The engine of claim 13, wherein further according to the second mode, fuel is additionally delivered to the engine via the intake fuel injector. 16. The engine of claim 9, wherein the pressure control module includes a first check valve and a second check valve, the first check valve being configured and arranged to effect fluid communication therethrough only along a flow direction extending from the storage tank toward the intake fuel injector,the second check valve being configured and arranged to effect fluid communication therethrough only along a flow direction extending from the intake fuel injector toward the storage tank. 17. The engine of claim 9, wherein the storage tank is configured to contemporaneously store a liquid phase of a fuel and a gaseous phase of the fuel, the liquid phase of the fuel being separated from the gaseous phase of the fuel by a free surface defined therebetween, the first aperture of the storage tank being arranged to effect fluid communication between the first aperture and the gaseous phase of the fuel along a flow path that does not include the liquid phase of the fuel,the second aperture of the storage tank being arranged to effect fluid communication between the second aperture and the liquid phase of the fuel along a flow path that does not include the gaseous phase of the fuel. 18. The engine of claim 17, wherein the pump is fluidly coupled to the direct fuel injector via a heat exchanger, the heat exchanger being thermally coupled to a heat source and configured to transfer heat from the heat source to a discharge flow from the pump, thereby evaporating the discharge flow from the pump via the heat exchanger. 19. A method for supplying a fuel to an engine, the method comprising: drawing a first flow of the fuel from a storage tank, the first flow of the fuel leaving the storage tank in a gaseous state;delivering the first flow of the fuel from the storage tank to a first fuel injector via a pressure control module;decreasing a pressure of the first flow of the fuel to less than a pressure inside the storage tank via the pressure control module;injecting the first flow of the fuel into a main combustion chamber of the engine via an oxidizer intake conduit of the engine;drawing a second flow of the fuel from the storage tank, the second flow of the fuel leaving the storage tank in a liquid state, the gaseous state of the fuel coexisting with the liquid state of the fuel within the storage tank;pumping the second flow of the fuel to a pressure that is higher than a pressure inside the storage tank;delivering the second flow of the fuel to a second fuel injector at a pressure that is higher than the pressure of the first flow of the fuel within the first fuel injector; andinjecting the second flow of the fuel directly into the main combustion chamber of the engine via the second fuel injector. 20. The method of claim 19, further comprising: drawing a third flow of the fuel from the storage tank, the third flow of the fuel leaving the storage tank in the gaseous state;delivering the third flow of the fuel from the storage tank to a third fuel injector via the pressure control module; andinjecting the third flow of the fuel into the main combustion chamber via a combustion pre-chamber.