Pressure control system and method for an agricultural planter

The invention claimed is: 1. A planter system comprising: an inlet configured to receive a fluid at a supply pressure; at least one hydraulic motor configured to control dispensing of an agricultural material at a dispensing rate; a control valve assembly comprising one or more control valves, wherein the one or more control valves of the control valve assembly are configured to receive a first portion of the fluid, and the one or more control valves of the control valve assembly are configured to distribute the first portion of the fluid to the at least one hydraulic motor at a demand pressure less than or substantially equal to the supply pressure; an unloading valve fluidly coupled to the inlet and to the one or more control valves of the control valve assembly, wherein the unloading valve is configured to separate the fluid from the inlet into the first portion and a remainder based at least in part on the dispensing rate, to direct the first portion of the fluid to the one or more control valves of the control valve assembly at an unloading pressure less than or substantially equal to the supply pressure and greater than or substantially equal to the demand pressure, to receive the first portion of the fluid after circulation through the at least one hydraulic motor, and to direct the remainder of the fluid to an outlet to bypass the one or more control valves of the control valve assembly; and the outlet configured to receive the first portion of the fluid from the one or more control valves and to receive the remainder of the fluid from the unloading valve. 2. The planter system of claim 1 , wherein the at least one hydraulic motor comprises a plurality of hydraulic motors in a parallel arrangement. 3. The planter system of claim 1 , wherein the agricultural material comprises seed, fertilizer, or any combination thereof. 4. The planter system of claim 3 , comprising a seed drive configured to distribute the seed onto a field at the dispensing rate. 5. The planter system of claim 1 , wherein the control valve assembly and the unloading valve are arranged in a shared housing. 6. The planter system of claim 1 , wherein the unloading valve is configured to control a ratio between the first portion and the remainder based at least in part on a difference between the supply pressure and the demand pressure. 7. The planter system of claim 1 , comprising a controller configured to control the supply pressure of the fluid received at the inlet, wherein the controller is configured to control the supply pressure to be greater than or substantially equal to the demand pressure. 8. The planter system of claim 7 , comprising a pump fluidly coupled to the inlet and communicatively coupled to the controller, wherein the pump is configured to output the fluid to the inlet. 9. The planter system of claim 7 , wherein the controller is communicatively coupled to the unloading valve, the controller is configured to control the unloading pressure to be substantially equal to the demand pressure within a first response time, the controller is configured to control the supply pressure to be substantially equal to the demand pressure within a second response time, and the first response time is less than the second response time. 10. A planter system comprising: an inlet configured to receive a fluid at a supply pressure; a pump fluidly coupled to the inlet and configured to output the fluid to the inlet; at least one hydraulically driven component; a control valve assembly comprising one or more control valves, wherein the one or more control valves of the control valve assembly are configured to receive a first portion of the fluid, and the one or more control valves of the control valve assembly are configured to distribute the first portion of the fluid to the at least one hydraulically driven component at a demand pressure less than or substantially equal to the supply pressure; an unloading valve fluidly coupled to the inlet and to the one or more control valves of the control valve assembly, wherein the unloading valve is configured to separate the fluid from the inlet into the first portion and a remainder, to direct the first portion of the fluid to the one or more control valves of the control valve assembly at an unloading pressure less than or substantially equal to the supply pressure and greater than or substantially equal to the demand pressure, to receive the first portion of the fluid after circulation through the at least one hydraulically driven component, and to direct the remainder of the fluid to an outlet to bypass the one or more control valves of the control valve assembly; and the outlet configured to receive the first portion of the fluid from the one or more control valves and to receive the remainder of the fluid from the unloading valve. 11. The planter system of claim 10 , comprising a controller communicatively coupled to the pump, wherein the controller is configured to control the supply pressure of the fluid received at the inlet to be greater than or substantially equal to the demand pressure. 12. The planter system of claim 11 , wherein the controller is communicatively coupled to the unloading valve, the controller is configured to control the unloading pressure to be substantially equal to the demand pressure within a first response time, the controller is configured to control the supply pressure to be substantially equal to the demand pressure within a second response time, and the first response time is less than the second response time. 13. The planter system of claim 10 , wherein the at least one hydraulically driven component comprises a plurality of hydraulic motors in a parallel arrangement. 14. The planter system of claim 10 , wherein the control valve assembly and the unloading valve are arranged in a shared housing. 15. The planter system of claim 10 , wherein the unloading valve is configured to control a ratio between the first portion and the remainder based at least in part on a difference between the supply pressure and the demand pressure. 16. A planter system, comprising: an unloading valve fluidly coupled to a pump via an inlet and an outlet, wherein the unloading valve is configured to receive a fluid at a supply pressure from the pump via the inlet, to supply a first portion of the fluid from the inlet to at least one hydraulically driven component of the planter system at an unloading pressure less than or substantially equal to the supply pressure, and to direct a remainder of the fluid to the pump via the outlet to bypass the at least one hydraulically driven component; and a controller communicatively coupled to the unloading valve and to the pump, wherein the controller is configured to adjust the pump to control the supply pressure of the fluid supplied to the unloading valve and to adjust the unloading valve to control the unloading pressure of the first portion supplied to the at least one hydraulically driven component of the planter system. 17. The planter system of claim 16 , comprising a control valve assembly configured to distribute the first portion of the fluid to the at least one hydraulically driven component of the planter system at a demand pressure. 18. The planter system of claim 17 , wherein the control valve assembly and the unloading valve are arranged in a shared housing. 19. The planter system of claim 16 , wherein the controller is configured to determine a demand pressure of the fluid supplied to the at least one hydraulically driven component, to control the unloa