Limiting system for a vehicle suspension component

What is claimed is: 1. A damper assembly, comprising: a tubular member including a sidewall and a cap positioned at an end of the sidewall, the sidewall and the cap defining an inner volume, wherein the sidewall comprises a first portion fixedly coupled with a second portion of the sidewall, wherein the first portion and the second portion define a shoulder of the sidewall; a rod extending within the inner volume; a primary piston positioned within the inner volume and coupled to the rod, the primary piston defining a first contact surface; a secondary piston having a second contact surface, an opposing second surface, and an inner cylindrical face that receives the rod, the second contact surface defining a channel extending between the inner cylindrical face and an outer periphery of the secondary piston, wherein the primary piston and the secondary piston separate the inner volume into a first working chamber, a second working chamber, and a recoil chamber; and a resilient member disposed between the secondary piston and the cap and thereby positioned to bias the secondary piston into direct engagement with the shoulder; wherein the first contact surface and the channel are configured to cooperatively define a flow conduit upon engagement between the primary piston and the secondary piston; wherein the second contact surface is configured to engage the first contact surface such that an open flow path is formed from the recoil chamber through (i) an aperture of the secondary piston and (ii) the flow conduit, upon engagement between the primary piston and the secondary piston. 2. The damper assembly of claim 1 , wherein the primary piston is moveable within the tubular member between a first location, an intermediate location, and an end of stroke, and wherein the primary piston is configured to maintain engagement with the secondary piston between the intermediate location and the end of stroke. 3. The damper assembly of claim 1 , wherein the recoil chamber is defined between the opposing second surface of the secondary piston and the cap. 4. The damper assembly of claim 2 , wherein the damper assembly provides a base level of damping as the primary piston moves between the first location and the intermediate location and an increased level of damping as the primary piston moves between the intermediate location and the end of stroke. 5. The damper assembly of claim 1 , wherein the primary piston, the first portion, and the second portion have circular cross-sectional shapes. 6. The damper assembly of claim 5 , wherein the first portion has a first diameter and the second portion has a second diameter, wherein the first diameter is greater than the second diameter, and wherein a transition between the first portion and the second portion defines the shoulder. 7. The damper assembly of claim 6 , wherein a diameter of the primary piston is less than the second diameter such that the primary piston is extendable along a length of the tubular member. 8. The damper assembly of claim 1 , wherein the aperture of the secondary piston is a central aperture positioned at a central portion of the secondary piston, wherein the rod extends through the central aperture. 9. A damper assembly, comprising: a housing having an end cap and defining an inner volume, the housing comprising a first portion fixedly coupled with a second portion, wherein a transition between the first portion and the second portion defines a shoulder; a primary piston positioned within the housing; and a limiter positioned between the primary piston and the end cap, the limiter comprising: a damper piston having a contact surface, an opposing second surface, and an inner cylindrical face, the primary piston and the damper piston separating the inner volume into a first working chamber, a second working chamber, and a recoil chamber; and a resilient member disposed within the recoil chamber, between the opposing second surface of the damper piston and the end cap, the resilient member thereby positioned to bias the damper piston into direct engagement with the shoulder; and a rod coupled to the primary piston and extending past the inner cylindrical face; wherein the contact surface defines a channel extending between the inner cylindrical face and an outer periphery of the damper piston across the contact surface, wherein the primary piston and the channel are configured to cooperatively define a first flow conduit upon engagement between the primary piston and the damper piston; and wherein an aperture of the damper piston defines a second flow conduit, and wherein the first flow conduit and the second flow conduit cooperate to define an open flow path from the recoil chamber. 10. The damper assembly of claim 9 , wherein the primary piston, the first portion, and the second portion have circular cross-sectional shapes. 11. The damper assembly of claim 10 , wherein the first portion has a first diameter and the second portion has a second diameter, wherein the first diameter is greater than the second diameter, and wherein the transition between the first portion and the second portion defines the shoulder. 12. The damper assembly of claim 11 , wherein the diameter of the primary piston is less than the second diameter such that the primary piston is extendable along the length of the housing. 13. The damper assembly of claim 9 , wherein the aperture of the damper piston is a central aperture positioned at a central portion of the damper piston. 14. The damper assembly of claim 13 , wherein the rod extends through the central aperture of the damper piston. 15. The damper assembly of claim 9 , wherein an end of the rod is coupled to the primary piston. 16. The damper assembly of claim 9 , wherein the primary piston is moveable within the housing between a first location, an intermediate location, and an end of stroke, and wherein the primary piston is configured to maintain engagement with the limiter between the intermediate location and the end of stroke. 17. The damper assembly of claim 16 , wherein the damper assembly provides a base level of damping as the primary piston moves between the first location and the intermediate location and an increased level of damping as the primary piston moves between the intermediate location and the end of stroke. 18. The damper assembly of claim 9 , wherein the recoil chamber is defined between the opposing second surface of the damper piston and the end cap. 19. A damper assembly, comprising: a housing having an end cap and defining an inner volume, wherein the housing comprises a first portion fixedly coupled with a second portion of the housing, wherein a transition between the first portion and the second portion defines a shoulder of the housing; a primary piston positioned within the housing; and a limiter positioned between the primary piston and the end cap, the limiter comprising: a damper piston having a contact surface, an opposing second surface, and an inner cylindrical face, the primary piston and the damper piston separating the inner volume into a first working chamber, a second working chamber, and a recoil chamber; and a resilient member disposed within the recoil chamber, between the opposing second surface of the damper piston and the end cap, the resilient member thereby positioned to bias the damper piston into direct engagement with the shoulder; and a rod coupled to the primary piston; wherein the contact surface defines a channel extending between the inner cylindrical face and an outer periphe