Methods and systems for dynamic weight management

The invention claimed is: 1. A method for weight transfer of a vehicle axle, comprising: compressing a vehicle suspension by actuating a pneumatic actuator comprising an outer housing with a cylinder abutted to a piston rod coupled to the vehicle suspension; adjusting a position of the pneumatic actuator to a first position; wherein, in the first position, a piston contacts a front wall of the outer housing of the pneumatic actuator and the piston rod is spaced away from the piston by a first distance and protrudes from a rear side of the outer housing of the pneumatic actuator by the first distance; deactivating the pneumatic actuator; and when deactivating the pneumatic actuator, maintaining at least nominal compression on the vehicle suspension with the piston rod spaced away from the piston of the cylinder via a biasing member, the piston configured to slide within the cylinder along a central axis of the cylinder. 2. The method of claim 1 , wherein deactivating the pneumatic actuator includes venting the pressure in the pneumatic actuator to decompress the vehicle suspension until the pressure decreases to a level providing the at least nominal compression on the vehicle suspension. 3. The method of claim 1 , wherein maintaining the at least nominal compression on the vehicle suspension includes maintaining a device linking the pneumatic actuator to the vehicle suspension taut without causing the weight transfer at the vehicle axle. 4. The method of claim 1 , wherein maintaining the at least nominal compression on the vehicle suspension when the pneumatic actuator is deactivated includes spacing the piston rod away from the piston of the cylinder a smaller distance along the central axis than when the pneumatic actuator is activated. 5. The method of claim 1 , wherein maintaining the at least nominal compression on the vehicle suspension includes using a spring force of the biasing member to overcome friction between components of the piston rod in contact with the cylinder and wherein the biasing member is a spring. 6. A weight transfer system for a vehicle, comprising; a vehicle suspension coupled to an axle of the vehicle; a pneumatic actuator comprising an outer housing having a cylinder piston abutted to a piston rod and configured to adjust the vehicle suspension based on a pressure in the pneumatic actuator, the piston rod coupled to the vehicle suspension through a linkage arrangement; and a spring member arranged in the cylinder piston and configured to exert a force on the piston rod along a central axis of the cylinder piston in a direction opposing a sliding of the piston rod when the vehicle suspension is decompressed; wherein the piston rod is in contact with the cylinder piston when the pneumatic actuator is pressurized to compress the vehicle suspension and at ambient pressure, the cylinder piston is in contact with a front wall of the outer housing of the pneumatic actuator and the piston rod is spaced away from the cylinder piston by a first distance and protrudes from a rear side of the outer housing of the pneumatic actuator by the first distance. 7. The weight transfer system of claim 6 , wherein the spring member is wrapped around the piston rod and wherein the spring member and a portion of the piston rod are surrounded by a casing, the casing abutted to the cylinder piston at one end. 8. The weight transfer system of claim 7 , wherein the spring member is configured to be compressed between a first end of the spring member abutting a first spring seat fixedly attached to the piston rod and a second end of the spring member abutting a second spring seat integrated into the casing. 9. The weight transfer system of claim 8 , wherein the second spring seat comprises a narrowing of an inner diameter of the casing along a portion of a length of the casing that does not surround the spring member, the length parallel with the central axis, and wherein an inner diameter of the second spring seat is narrower than an outer diameter of the spring member. 10. The weight transfer system of claim 8 , wherein the second spring seat comprises a ring with a first outer diameter and a first inner diameter, the first outer diameter equal to a second inner diameter of the casing and the first inner diameter narrower than a second outer diameter of the spring member. 11. The weight transfer system of claim 6 , wherein when the pneumatic actuator is depressurized to decompress the vehicle suspension, the spring member is less compressed than when the pneumatic actuator is pressurized to compress the vehicle suspension. 12. The weight transfer system of claim 6 , wherein a nominal amount of compression is maintained on the vehicle suspension by the force exerted on the piston rod by the spring member when the pneumatic actuator is depressurized. 13. A vehicle suspension system, comprising: a lift mechanism including a crank coupled to a chain, the chain extending between a truck and a carrier of the lift mechanism; and a pneumatic actuator configured to adjust the lift mechanism by rotating the crank, the pneumatic actuator including: a piston coupled to a piston tube, both the piston and the piston tube enclosed by an outer housing of the pneumatic actuator; a rod extending along a central axis of the pneumatic actuator, a first portion of the rod enclosed by the piston tube and a second portion of the rod protruding from the piston tube and coupled to the crank; and a spring enclosed by the piston tube and coiling around the rod, the spring extending between a first end abutting a first spring seat fixedly attached to the rod and a second end abutting a second spring seat fixedly attached to the piston tube; wherein the pneumatic actuator is configured to be in a first position when the pneumatic actuator is at ambient pressure and wherein in the first position, the piston contacts a front wall of the outer housing of the pneumatic actuator and the rod is spaced away from the piston by a first distance and protrudes from a rear side of the outer housing of the pneumatic actuator by the first distance. 14. The system of claim 13 , wherein the spring has a stiffness that exerts a spring force both on the second spring seat along the central axis of the pneumatic actuator and along a first direction towards the front wall of the outer housing of the pneumatic actuator and on the first spring seat along the central axis of the pneumatic actuator along a second direction, the second direction opposite of the first direction. 15. The system of claim 13 , wherein the rod, when moved to protrude from the rear side of the outer housing of the pneumatic actuator by the first distance, is configured to rotate the crank and maintain a first amount of tension on the chain. 16. The system of claim 15 , wherein the pneumatic actuator is configured to be in a second position when the pneumatic actuator is at a pressure greater than ambient pressure and wherein in the second position, the piston is spaced away from the front wall of the outer housing of the pneumatic actuator by a second distance that is greater than the first distance and the rod is in contact with the piston and protrudes from the rear side of the outer housing of the pneumatic actuator by the second distance. 17. The system of claim 16 , wherein the rod, when moved to protrude from the rear side of the outer housing of the pneumatic actuator by the second distance, is configured to increase the rotation of the crank and exert a second amount of tension on the chain, the second amount greater than the first amount