Load path control mechanism

The invention claimed is: 1. A load path control mechanism enabling a controlled distribution of loads from a vehicle body to a vehicle frame comprising: a frame rail substantially parallel to a first axis and defining an axially extending inner chamber therein; a frame crossmember substantially parallel to a second axis perpendicular to the first axis and fixed to an inboard side of the frame rail at a seat location on the first axis; a coupling bracket disposed in the inner chamber and fixed to the frame rail and aligned in parallel with the frame crossmember and the coupling bracket having a first projected area on a plane normal to the second axis; and a spacer bracket disposed on a first side of the frame rail opposite the coupling bracket and having a second projected area on the plane normal to the second axis at least partially overlapping the first projected area and the spacer bracket oriented for engagement by a rocker upon deformation of the rocker in a second axial direction parallel to the second axis and the frame rail having a deformation mode responsive to a first load in the second axial direction against the spacer bracket with the spacer bracket deflected in the second axial direction and the first side of the frame rail deflected against the coupling bracket. 2. The load path control mechanism of claim 1 , wherein the spacer bracket has a C-shaped cross section and fixed to a body mount located on an outboard side of the frame rail and to the outboard side of the frame rail. 3. The load path control mechanism of claim 1 , wherein the spacer bracket having a frustoconical shape and fixed to the outboard side of the frame rail. 4. The load path control mechanism of claim 1 , wherein the coupling bracket having a C-shaped cross section and having an open side disposed toward the frame crossmember and having edges bordering the open side fixed to the frame crossmember. 5. The load path control mechanism of claim 1 , wherein the coupling bracket has an open ended box shape. 6. The load path control mechanism of claim 1 , wherein the frame crossmember having a first bending stiffness proximate to the frame rail and the frame crossmember having a second bending stiffness at a first location spaced a short distance from the frame rail with the second bending stiffness greater than the first bending stiffness and the second bending stiffness extending along the length of the frame crossmember in a direction away from the frame rail such that deflection of the frame crossmember responsive to a load in a direction parallel to the second axis against the frame is more pronounced at a location proximate to the frame rail than distal to the frame rail. 7. The load path control mechanism of claim 6 , wherein the spacer bracket having a C-shaped cross section and fixed to a body mount located on an outboard side of the frame rail and to the outboard side of the frame rail. 8. The load path control mechanism of claim 6 , wherein the spacer bracket having a frustoconical shape and fixed to the outboard side of the frame rail. 9. The load path control mechanism of claim 6 , wherein the coupling bracket having a C-shaped cross section and having an open side disposed toward the frame crossmember and having edges bordering the open side fixed to the frame crossmember. 10. The load path control mechanism of claim 6 , wherein the coupling bracket has an open ended box shape. 11. A load path control mechanism enabling a controlled distribution of loads from a vehicle body to a vehicle frame comprising: a frame rail substantially parallel to a first axis and defining an axially extending inner chamber therein; a frame crossmember substantially parallel to a second axis perpendicular to the first axis and fixed to an inboard side of the frame rail at a seat location on the first axis; a coupling bracket disposed in the inner chamber and fixed to the frame rail and aligned in parallel with the frame crossmember and the coupling bracket having a first projected area on a plane normal to the second axis; and a spacer bracket disposed on a first side of the frame rail opposite the coupling bracket and having a second projected area on the plane normal to the second axis at least partially overlapping the first projected area and the spacer bracket oriented for engagement by a rocker upon deformation of the rocker in a second axial direction parallel to the second axis and the frame rail having a deformation mode responsive to a first load in the second axial direction against the spacer bracket with the spacer bracket deflected in the second axial direction and the first side of the frame rail deflected against the coupling bracket; and wherein only one spacer bracket and one coupling bracket are disposed on the frame rail for a seat position. 12. The load path control mechanism of claim 11 , wherein the spacer bracket having a C-shaped cross section and fixed to a body mount located on an outboard side of the frame rail and to the outboard side of the frame rail. 13. The load path control mechanism of claim 11 , wherein the spacer bracket having a frustoconical shape and fixed to the outboard side of the frame rail. 14. The load path control mechanism of claim 11 , wherein the coupling bracket having a C-shaped cross section and having an open side disposed toward the frame crossmember and having edges bordering the open side fixed to the frame crossmember. 15. The load path control mechanism of claim 11 , wherein the coupling bracket has an open ended box shape. 16. A load path control mechanism enabling a controlled distribution of loads from a vehicle body to a vehicle frame comprising: a first frame rail substantially parallel to a first axis and defining an axially extending first inner chamber therein; a second frame rail substantially parallel to the first axis and defining an axially extending second inner chamber therein; a frame crossmember substantially parallel to a second axis perpendicular to the first axis and disposed between and connecting the frame rails and located at a seat location on the first axis; a first coupling bracket disposed in the first inner chamber and fixed to the first frame rail and aligned in parallel with the frame crossmember and the first coupling bracket having a first projected coupling area on a plane normal to the second axis; a second coupling bracket disposed in the second inner chamber and fixed to the second frame rail and aligned in parallel with the frame crossmember and the second coupling bracket having a second projected coupling area on a plane normal to the second axis; a first spacer bracket disposed on a first side of the first frame rail opposite the first coupling bracket and having a first projected spacer area on the plane normal to the second axis at least partially overlapping the first projected coupling area and the first spacer bracket oriented for engagement by a first rocker upon deformation of the first rocker in a second axial direction parallel to the second axis and the first frame rail having a deformation mode responsive to a first load in the second axial direction against the first spacer bracket with the first spacer bracket deflected in the second axial direction and the first side of the first frame rail deflected against the first coupling bracket; a second spacer bracket disposed on a first side of the second frame rail opposite the second coupling bracket and having a second projected spacer area on the plane normal to the second axis at least partially overlapping the second projecte