Slow response solenoid hydraulic valve, and associated systems and methods

We claim: 1. A hydraulic valve for dampening pressure spikes, comprising: a spool configured to move axially inside the hydraulic valve; a sleeve configured to at least partially house the spool, wherein a location of the spool with respect to the sleeve determines a flow of a working fluid through the hydraulic valve; and a viscous damper at least partially housed inside an opening in the spool, wherein the viscous damper comprises a self-centering feature configured to align the viscous damper with an axial direction of the spool, wherein the self-centering feature comprises a round end seated against correspondingly round end shaped surface of an end cap, wherein the viscous damper is generally round, wherein the viscous damper includes at least one axial non-circumferential groove that only partially extends along an axial direction of the viscous damper thus increasing a clearance between the viscous damper and the opening in the spool, wherein the groove is located entirely within a space that lies between the viscous damper and the opening in the spool, and wherein an entire length of the groove is parallel with a main longitudinal center axis of the valve, wherein a viscous friction between the viscous damper and the opening in the spool slows a motion of the spool. 2. The hydraulic valve of claim 1 , wherein a pressure of a pilot fluid between the viscous damper and the opening in the spool slows the motion of the spool. 3. The hydraulic valve of claim 1 , wherein the viscous damper is a first viscous damper and the opening is a first opening at a first side of the spool, the hydraulic valve further comprising a second viscous damper at least partially housed inside a second opening at a second side of the spool, wherein the second side of the spool is opposite from the first side of the spool, and wherein the viscous friction between the second viscous damper and the second opening in the spool slows the motion of the spool. 4. The hydraulic valve of claim 3 , wherein the hydraulic valve comprises a first port (C 1 ) in a fluid communication with a first end user and a second port (C 2 ) in the fluid communication with a second end user, wherein in a first position of the spool, the first port (C 1 ) and the second port (C 2 ) are connected to a working fluid in a de-energized state, wherein in a second position of the spool the first port (C 1 ) is connected to the working fluid in the de-energized state and the second port (C 2 ) is connected to the working fluid in an energized state, and wherein in a third position of the spool the first port (C 1 ) is connected to the working fluid in the energized state and the second port (C 2 ) is connected to the working fluid in the de-energized state. 5. The hydraulic valve of claim 1 , wherein the viscous damper includes a plurality of radial grooves configured to center the viscous damper within the opening in the spool. 6. The hydraulic valve of claim 5 , wherein at least one of the plurality of radial grooves intersects with the at least one axial non-circumferential groove. 7. The hydraulic valve of claim 1 , further comprising a bias spring configured to bias the spool. 8. The hydraulic valve of claim 1 , wherein the sleeve comprises a scalloped opening configured to engage with a cooperating opening in the spool by a narrow side of the scalloped opening that limits a flow of the working fluid. 9. A method for dampening pressure spikes, comprising: providing a pilot fluid at a predetermined pressure to a hydraulic valve; in response to the pressure of the pilot fluid, axially moving a spool within a sleeve; counteracting a motion of the spool by viscous friction of a viscous damper that is at least partially housed inside an opening in the spool, wherein the viscous damper comprises a self-centering feature configured to align the viscous damper with an axial direction of the spool, wherein the self-centering feature comprises a round end seated against correspondingly round end shaped surface of an end cap, wherein the viscous damper is generally round, wherein the viscous damper includes at least one axial non-circumferential groove that only partially extends along an axial direction of the viscous damper thus increasing a clearance between the viscous damper and the opening in the spool, wherein the groove is located entirely within a space that lies between the viscous damper and the opening in the spool, and wherein an entire length of the groove is parallel with a main longitudinal center axis of the valve; and in response to axially moving the spool, providing a path for a working fluid through the hydraulic valve. 10. The method of claim 9 , further comprising biasing the spool by a bias spring. 11. The method of claim 9 , wherein the viscous damper includes a plurality of radial grooves configured to center the viscous damper inside the spool. 12. The method of claim 11 , wherein at least one of the plurality of radial grooves intersects with the at least one axial non-circumferential groove. 13. The method of claim 9 , wherein the viscous damper is a first viscous damper and the opening is a first opening at a first side of the spool, the hydraulic valve further comprising a second viscous damper at least partially housed inside a second opening at a second side of the spool, wherein the second side of the spool is opposite from the first side of the spool, and wherein the viscous friction between the second viscous damper and the second opening in the spool slows the motion of the spool. 14. The method of claim 13 , wherein the hydraulic valve comprises a first port (C 1 ) in a fluid communication with a first end user and a second port (C 2 ) in the fluid communication with a second end user, wherein in a first position of the spool, the first port (C 1 ) and the second port (C 2 ) are connected to a working fluid in a de-energized state, wherein in a second position of the spool the first port (C 1 ) is connected to the working fluid in the de-energized state and the second port (C 2 ) is connected to the working fluid in an energized state, and wherein in a third position of the spool the first port (C 1 ) is connected to the working fluid in the energized state and the second port (C 2 ) is connected to the working fluid in the de-energized state. 15. The method of claim 13 , further comprising: biasing a first side of the spool with a first bias spring; and biasing a second side of the spool with a second bias spring, wherein the second side is opposite from the first side.