Low power hydraulic valves with increased rate-of-flow

What is claimed is: 1. A hydraulic valve comprising: an outer valve housing piece including an exterior threaded portion for securing the hydraulic valve within a valve manifold; a solenoid assembly including a solenoid coil contained within a solenoid housing, the outer valve housing piece being mounted adjacent to the solenoid assembly; a valve cage coupled to the outer valve housing piece, the valve cage including an axial port positioned along an axis that extends through the solenoid coil, the valve cage also defining a side port; a pilot-poppet valve seat positioned within the outer valve housing piece, the pilot-poppet valve seat and the valve cage being mechanically secured relative to each other such that relative movement between the pilot-poppet valve seat and the valve cage along the axis is prevented, the pilot-poppet valve seat defining a pilot port, and the pilot- poppet valve seat defining first and second opposite sides; a pilot-poppet positioned at the second side of the pilot-poppet valve seat, the pilot-poppet being movable relative to the pilot-poppet valve seat along the axis between a first position and a second position, wherein the pilot-poppet closes the pilot port when in the first position, and wherein the pilot port is open when the pilot-poppet is in the second position; a pilot-poppet spring that biases the pilot-poppet in a first axial direction toward the first position, wherein the pilot-poppet is driven in a second axial direction toward the second position when the solenoid coil is energized; a main-poppet positioned at the first side of the pilot-poppet valve seat, the main-poppet being mechanically isolated from the pilot-poppet by the pilot-poppet valve seat, the main-poppet being positioned within the valve cage and being movable along the axis between a closed position and an open position, wherein when the main-poppet is in the closed position, the main-poppet engages a main valve seat defined by the valve cage to prevent direct fluid communication between the axial port and the side port, and wherein when the main-poppet is in the open position, the main-poppet is displaced from the main valve seat to allow direct fluid communication between the axial port and the side port; a main-poppet spring captured between the pilot-poppet valve seat and the main-poppet for biasing the main-poppet toward the closed position; and a main-poppet chamber defined between the main-poppet and the pilot-poppet valve seat, the main-poppet including a chamber pressurization orifice that provides fluid communication between the side port and the main-poppet chamber; wherein when the pilot-poppet is in the first position and the pressure is higher at the side port than the axial port, the main-poppet chamber is pressurized from the side port through the chamber pressurization orifice such that spring force from the main- poppet spring combined with pressure within the main-poppet chamber cooperate to hold the main-poppet in the closed position; and wherein when the pilot-poppet is in the second position and the pressure is higher at the side port than the axial port, the pilot port provides fluid communication between the main-poppet chamber and a passage that extends to the axial port such that pressure within the main-poppet chamber is relieved through the passage, thereby allowing pressure from the side port acting on an exterior of the main-poppet to move the main-poppet from the closed position to the open position against the bias of the main-poppet spring, and wherein the passage includes at least a portion drilled through the valve cage, wherein the portion includes a first section and a second section, the first section extending at an oblique angle relative to the axis from the axial port to the second section, and the second section extending parallel to the axis from adjacent the pilot-poppet valve seat to the first section. 2. The hydraulic valve of claim 1 , wherein the pilot-poppet provides a pressure relief function when the pressure at the side port exceeds a predetermined level. 3. The hydraulic valve of claim 2 , wherein the predetermined level is dependent upon a spring force applied to the pilot-poppet by the pilot-poppet spring and an area of the pilot-poppet exposed through the pilot port to pressure within the main-poppet chamber. 4. The hydraulic valve of claim 3 , wherein when the main-poppet is in the closed position and the pressure in the main-poppet chamber is pressurized to the predetermined level by pressure from the side port, the pressure within the main-poppet chamber forces the pilot-poppet in the second direction to open the pilot port and relieve pressure from the main-poppet chamber through the passage to the axial port, and wherein when the pressure in the main-poppet chamber is relieved, the pressure from the side port acting on the exterior of the main-poppet moves the main-poppet from the closed position to the open position against the bias of the main-poppet spring such that pressure at the side port is relieved to the axial port. 5. The hydraulic valve of claim 1 , wherein the passage includes a one-way check valve that allows fluid flow in a first direction from the pilot port toward the axial port and prevent fluid flow in a second direction from the axial port toward the pilot port, and wherein when the pressure at the axial port is higher than the pressure at the side port and is sufficiently high to overcome the main-poppet spring, the main-poppet is forced by the pressure acting on the main-poppet from the closed position to the open position. 6. The hydraulic valve of claim 1 , wherein the second section extends through exterior threads defined by the valve cage. 7. The hydraulic valve of claim 1 , wherein the pilot-poppet is integrated within a magnetic core configured to be driven in the second direction along the axis when the solenoid coil is energized by electrical current flowing through the solenoid coil, wherein the hydraulic valve further includes a core tube that extends through the solenoid coil along the axis, wherein the magnetic core is configured to move along the axis within the core tube. 8. The hydraulic valve of claim 7 , wherein the solenoid housing includes a first end and an opposite second end, wherein the core tube extends between the first and second ends, wherein the core tube includes a second end secured at the second end of the solenoid housing and a first end that extends beyond the first end of the solenoid housing, and wherein the second end of the core tube defines external core tube threads. 9. The hydraulic valve of claim 8 , wherein the outer valve housing piece is mounted at the first end of the solenoid housing, wherein the outer valve housing piece includes first and second sets of internal threads, and wherein the second set of internal threads engages the external core tube threads to secure the outer valve housing piece adjacent the solenoid housing. 10. The hydraulic valve of claim 9 , wherein the valve cage defines external cage threads that engage the first set of internal threads of the outer valve housing piece to secure the valve cage within the outer valve housing piece. 11. The hydraulic valve of claim 10 , wherein the pilot-poppet valve seat is clamped between an end of the valve cage and the second end of the core tube. 12. The hydraulic valve of claim 11 , wherein a first annular seal is defined by annular axial contact between the outer valve housing piece and the valve cage, wherein a second annular seal is defined by annular axial contact between the end of the valve cage and the first side of the pilot-poppet valve seat, and wherein a third annular seal is