Roll angle stop arrangement for a suspension system in an off-road vehicle

The invention claimed is: 1. An off-road vehicle, comprising: a chassis; an axle carriage attached to or forming a part of the chassis; a pair of suspension cylinders, each said suspension cylinder being connected to said axle carriage; a rigid axle mounted to the axle carriage and movable in vertical directions relative to the axle carriage using the pair of suspension cylinders, the axle including a first pair of roll angle stops which engage the axle carriage when the axle is at or near a fully lowered position relative to the axle carriage, and a second pair of roll angle stops which engage the axle carriage when the axle is at or near a fully raised position relative to the axle carriage. 2. The off-road vehicle of claim 1 , wherein the first pair of roll angle stops each include a generally vertically arranged stop surface, and the second pair of roll angle stops each include a generally horizontally arranged stop surface. 3. The off-road vehicle of claim 2 , wherein the axle carriage includes a generally vertically arranged slot, and the axle includes a generally cylindrical pivot member located approximately midway between the ends of the axle and having a longitudinal axis extending generally in a fore-aft direction of the off-road vehicle, the pivot member being positioned and vertically movable within the slot of the axle carriage. 4. The off-road vehicle of claim 3 , wherein the axle carriage includes a pair of downwardly extending legs defining said slot, and the axle includes an upwardly extending block with a pair of opposed side surfaces respectively defining said generally vertically arranged stop surfaces, each said generally vertically arranged stop surface being engagable with a corresponding said leg. 5. The off-road vehicle of claim 4 , wherein said axle carriage includes an upwardly extending recess between said legs and said block fits within said recess when the axle is in the fully raised position. 6. The off-road vehicle of claim 4 , wherein said pair of generally horizontally arranged stop surfaces are positioned on each lateral side of the block. 7. The off-road vehicle of claim 6 , wherein said second pair of roll angle stops each include a plate mounted to a top of the axle, each said plate having an upper surface defining the generally horizontally arranged stop surface. 8. The off-road vehicle of claim 7 , wherein the upper surface of each said plate is positioned at a predetermined angle relative to horizontal. 9. The off-road vehicle of claim 1 , wherein the first pair of roll angle stops engage the axle carriage when the axle is within a first predetermined range of movement relative to the axle carriage, and the second pair of roll angle stops engage the axle carriage when the axle is within a second predetermined range of movement relative to the axle carriage. 10. The off-road vehicle of claim 9 , wherein the first predetermined range of movement is adjacent to the fully lowered position, and the second predetermined range of movement is adjacent to the fully raised position. 11. The off-road vehicle of claim 9 , wherein the axle has a maximum roll angle which varies according to a first mathematical relationship when the axle is at any position within the first predetermined range of movement, and wherein the axle has a maximum roll angle which varies according to a second mathematical relationship when the axle is at any position within the second predetermined range of movement. 12. The off-road vehicle of claim 11 , wherein the first mathematical relationship and the second mathematical relationship are each generally linear relationships, with the second mathematical relationship having a steeper slope than the first mathematical relationship. 13. The off-road vehicle of claim 12 , wherein a distinct crossover point exists between the first mathematical relationship and the second mathematical relationship. 14. The off-road vehicle of claim 11 , wherein the axle has a smallest roll angle when the axle is at the fully raised position, and the axle has a greatest roll angle when the axle is at the fully lowered position. 15. The off-road vehicle of claim 1 , wherein the axle is at the fully lowered position when the pivot member is seated against a bottom of the slot. 16. An off-road vehicle, comprising: a chassis; an axle carriage attached to or forming a part of the chassis; a pair of suspension cylinders, each said suspension cylinder being connected to said axle carriage; a rigid axle mounted to the axle carriage and movable in vertical directions relative to the axle carriage using the pair of suspension cylinders, the axle including a first pair of roll angle stops which engage the axle carriage when the axle is within a first predetermined range of movement relative to the axle carriage, and a second pair of roll angle stops which engage the axle carriage when the axle is within a second predetermined range of movement relative to the axle carriage. 17. The off-road vehicle of claim 16 , wherein the first predetermined range of movement is adjacent to a fully lowered position, and the second predetermined range of movement is adjacent to a fully raised position. 18. The off-road vehicle of claim 16 , wherein the axle has a maximum roll angle which varies according to a first mathematical relationship when the axle is at any position within the first predetermined range of movement, and wherein the axle has a maximum roll angle which varies according to a second mathematical relationship when the axle is at any position within the second predetermined range of movement. 19. The off-road vehicle of claim 18 , wherein the first mathematical relationship and the second mathematical relationship are each generally linear relationships, with the second mathematical relationship having a steeper slope than the first mathematical relationship. 20. The off-road vehicle of claim 19 , wherein a distinct crossover point exists between the first mathematical relationship and the second mathematical relationship.