Propel circuit and work circuit combinations for a work machine

What is claimed is: 1. A hydraulic circuit architecture for a mobile work vehicle, the hydraulic circuit architecture comprising: a drive hydraulic pump adapted to be driven by a prime mover, the drive hydraulic pump having a high pressure side and a low pressure side; a hydraulic work circuit adapted for connection to at least one actuator for driving a work implement of the mobile work vehicle; a hydraulic propel circuit including a propel hydraulic motor adapted to be connected to a drive train of the mobile work vehicle, the hydraulic propel circuit also including a hydraulic accumulator; and a circuit selector for selectively connecting the high pressure side of the drive hydraulic pump to the hydraulic work circuit and the hydraulic propel circuit; wherein the hydraulic circuit architecture is operable in: a) a first mode where the hydraulic propel circuit is connected to the high pressure side of the drive hydraulic pump and the hydraulic work circuit is disconnected from the high pressure side of the drive hydraulic pump; and b) a second mode where the hydraulic work circuit is connected to the high pressure side of the drive hydraulic pump and the hydraulic propel circuit is disconnected from the high pressure side of the drive hydraulic pump so that when the hydraulic circuit architecture is in the second mode, stored energy from the hydraulic accumulator can be used to drive the propel hydraulic motor to cause propulsion of the mobile work vehicle. 2. The hydraulic circuit architecture of claim 1 , further comprising a cross-over hydraulic flow line that provides fluid communication between the hydraulic work circuit and the hydraulic propel circuit, wherein a cross-over valve is provided for opening and closing the cross-over hydraulic flow line. 3. The hydraulic circuit architecture of claim 2 , wherein the cross-over valve controls a flow rate through the cross-over hydraulic flow line. 4. The hydraulic circuit architecture of claim 2 , wherein the cross-over hydraulic flow line allows the stored energy from the hydraulic accumulator to be used to drive the at least one actuator of the hydraulic work circuit. 5. The hydraulic circuit architecture of claim 2 , wherein the hydraulic circuit architecture is operable in a third mode where both the hydraulic work circuit and the hydraulic propel circuit receive no hydraulic fluid flow from the high pressure side of the drive hydraulic pump, and wherein the cross-over hydraulic flow line allows the stored energy from the hydraulic accumulator to be used to drive the at least one actuator of the hydraulic work circuit and the stored energy from the hydraulic accumulator drives the propel hydraulic motor. 6. The hydraulic circuit architecture of claim 1 , wherein the propel hydraulic motor is a variable displacement hydraulic pump/motor, wherein the hydraulic circuit architecture is operable in a charge mode where hydraulic fluid pumped by the variable displacement hydraulic pump/motor is used to charge the hydraulic accumulator. 7. The hydraulic circuit architecture of claim 6 , wherein kinetic energy of the mobile work vehicle is transformed into added stored energy that is stored in the hydraulic accumulator when the mobile work vehicle decelerates. 8. The hydraulic circuit architecture of claim 1 , wherein the drive hydraulic pump is a hydraulic pump/motor, and wherein hydraulic fluid from the hydraulic accumulator can be used to drive the hydraulic pump/motor. 9. The hydraulic circuit architecture of claim 8 , wherein the hydraulic pump/motor may start the prime mover when the hydraulic pump/motor is driven by the hydraulic fluid from the hydraulic accumulator. 10. The hydraulic circuit architecture of claim 1 , wherein the circuit selector includes a valve. 11. The hydraulic circuit architecture of claim 1 , wherein the circuit selector includes a plurality of valves. 12. The hydraulic circuit architecture of claim 1 , further comprising an isolator valve for selectively isolating the hydraulic accumulator from the hydraulic propel circuit. 13. The hydraulic circuit architecture of claim 12 , wherein a maximum working pressure of the hydraulic propel circuit is higher than a working pressure of the hydraulic accumulator. 14. The hydraulic circuit architecture of claim 12 , wherein a maximum working pressure of the hydraulic propel circuit is higher than a rated pressure of the hydraulic accumulator. 15. The hydraulic circuit architecture of claim 1 , further comprising a hydraulic steering circuit in fluid communication with the hydraulic propel circuit. 16. The hydraulic circuit architecture of claim 1 , wherein the mobile work vehicle is a fork lift, wherein the prime mover is a combustion engine mechanically coupled to the drive hydraulic pump, wherein the hydraulic work circuit is hydraulically coupled to the at least one actuator, and wherein the at least one actuator includes a first hydraulic cylinder for lifting a fork of the fork lift, a second hydraulic cylinder for tilting the fork, and a third hydraulic cylinder for laterally moving the fork. 17. The hydraulic circuit architecture of claim 16 , wherein the first hydraulic cylinder is a main stage cylinder, wherein the at least one actuator further includes a secondary stage set of hydraulic cylinders that includes at least one second stage cylinder for lifting the fork of the fork lift. 18. The hydraulic circuit architecture of claim 1 , wherein the drive hydraulic pump is an only drive hydraulic pump of the hydraulic circuit architecture. 19. The hydraulic circuit architecture of claim 18 , wherein the drive hydraulic pump includes a charge pump. 20. The hydraulic circuit architecture of claim 1 , wherein the drive hydraulic pump is a single hydraulic pump of the hydraulic circuit architecture that is adapted to power at least the hydraulic work circuit and the hydraulic propel circuit. 21. The hydraulic circuit architecture of claim 20 , wherein the single hydraulic pump includes a charge pump. 22. A hydraulic circuit architecture for a mobile work vehicle having a hydraulic pump coupled to a prime mover, the hydraulic circuit architecture comprising: a hydraulic work circuit adapted for connection to at least one actuator for driving a work implement of the mobile work vehicle; a hydraulic propel circuit including a propel hydraulic motor adapted to be connected to a drive train of the mobile work vehicle, the hydraulic propel circuit also including a hydraulic accumulator; a high pressure line leading from a high pressure side of the hydraulic pump to the hydraulic propel circuit and a cross-over hydraulic flow line that selectively provides fluid communication between the hydraulic work circuit and the high pressure line downstream of the accumulator, the cross-over hydraulic flow line being adapted to transfer energy from the hydraulic accumulator to the hydraulic work circuit when the hydraulic circuit architecture is operated in a first mode; wherein the hydraulic circuit architecture also is operable in at least a second mode where the hydraulic work circuit is hydraulically isolated from the hydraulic propel circuit, where the prime mover powers the hydraulic work circuit via the hydraulic pump, and where the hydraulic accumulator powers the propel hydraulic motor. 23. The hydraulic circuit architecture of claim 22 , wherein the hydraulic pump is a single hydraulic pump adapted to be driven by the prime mover.