Axle and spindle for heavy-duty vehicle and method

What is claimed is: 1. A method of making an axle assembly for a heavy-duty vehicle, the method comprising the steps of: providing a central tube; providing a hollow member; producing an axle spindle by: forming a first cylindrical section on the hollow member to have a portion with a first diameter; forming a second cylindrical section on the hollow member integrally with and extending in a direction away from the first cylindrical section, the second cylindrical section having a second diameter less than the first diameter; forming an unfinished transition section on the hollow member integrally with, and located between, the first cylindrical section and the second cylindrical section, the unfinished transition section tapering from the first cylindrical section to the second cylindrical section; forming a chucking land pad on the unfinished transition section; friction welding the axle spindle to the central tube by engaging the chucking land pad and rotating the axle spindle relative to the central tube; and machining away the chucking land to form a finished transition section. 2. The method of claim 1 wherein the machining step further includes the step of machining the chucking land pad to form an antilock braking system sensor bracket locator nub on the finished tapering transition section. 3. The method of claim 2 further including the step of locating an antilock braking system sensor bracket on the antilock braking system sensor bracket locator nub and fixing the antilock braking system sensor bracket to the axle spindle. 4. An axle spindle for a heavy-duty vehicle, the axle spindle for receiving at least one bearing assembly to support a hub for rotation relative to the axle spindle, the axle spindle comprising: a tubular first cylindrical section having a portion with a first outer diameter, the first cylindrical section having an end surface connectable with an axle central tube; a tubular second cylindrical section integrally and coaxially formed with and extending in a direction away from the first cylindrical section, the second cylindrical section having a second outer diameter less than the first diameter of the first cylindrical section, the second cylindrical section having at least one bearing support surface with a bearing support diameter to receive and support a bearing assembly; a tubular transition section integrally and coaxially formed with and located between the first cylindrical section and the second cylindrical section; an annular shoulder portion integrally and coaxially formed in an end segment of the tubular transition section adjacent the second cylindrical section, the shoulder portion having an annular shoulder surface for engaging an annular surface of the bearing assembly; an annular profile located in the shoulder portion between the annular shoulder surface and the bearing support surface, the annular profile defined by a surface having a third diameter that is not less than the bearing support diameter of the bearing support surface; and the annular profile defined by a first annular surface with a first radius taken in a plane containing a longitudinal central axis of the axle spindle, the first annular surface located between the annular shoulder surface and the bearing support surface, a second annular surface with a second radius taken in the plane containing the longitudinal central axis of the axle spindle, the second annular surface being located between the first annular surface and the bearing support surface, the second radius of the second annular surface being greater than the first radius of the first annular surface. 5. The axle spindle of claim 4 further including an antilock braking system sensor bracket locator nub formed in the tubular transition section. 6. The axle assembly of claim 5 further including an antilock braking system bracket engaging a surface of the antilock braking system sensor bracket locator nub, the antilock braking system bracket being fixed to the axle spindle. 7. The axle spindle of claim 4 wherein a rate of change in section modulus taken at an axial location between adjacent sections spaced apart in 0.050 inch increments from the shoulder surface in a direction towards the end surface of the tubular first cylindrical section varies no more than 10% for every rate of change in section modulus. 8. The axle spindle of claim 4 wherein the annular profile has a frustoconical segment extending in a direction radially inward from the annular shoulder surface. 9. The axle spindle of claim 8 wherein the frustoconical segment extends at an angle relative to a longitudinal central axis of the spindle in the range of 45° to 85°. 10. The axle spindle of claim 8 wherein the first radius is located between the frustoconical segment and the at least one bearing support surface of the second cylindrical section. 11. The axle spindle of claim 4 wherein the second radius is in a range from 0.375 inch to 0.625 inch and the first radius is in a range from 0.060 inch to 0.125 inch. 12. The axle spindle of claim 4 wherein the ratio of the second radius to the first radius is at least 5:1. 13. The axle spindle of claim 4 further including the transition section having an arcuate inner surface with a radius taken in the plane containing a longitudinal central axis of the axle spindle in a range of 8.00 inches to 12.00 inches. 14. An axle spindle for a heavy-duty vehicle wheel end, the axle spindle for receiving at least one bearing assembly for supporting a hub for rotation, the axle spindle comprising: a tubular first cylindrical section having a portion with a first outer diameter, the first cylindrical section having an end surface connectable with an axle central tube; a tubular second cylindrical section integrally and coaxially formed with and extending in a direction away from the first cylindrical section, the second cylindrical section having a second outer diameter less than the first diameter of the first cylindrical section, the second cylindrical section having at least one bearing support surface with a bearing support diameter to receive and support a bearing assembly; a tubular transition section integrally and coaxially formed with and located between the first cylindrical section and the second cylindrical section; an annular shoulder portion integrally and coaxially formed in an end segment of the transition section adjacent the second cylindrical section, the shoulder portion having an annular shoulder surface for engaging an annular surface of the bearing assembly; and an annular profile located in the shoulder portion between the annular shoulder surface and the at least one bearing support surface, the annular profile defined by a surface having a third diameter that is not less than the bearing support diameter of the bearing support surface; wherein the annular profile has a first radiused surface with a first radius located between the annular shoulder surface and the at least one bearing support surface, a second radiused surface with a second radius located between the first radiused surface and the at least one bearing support surface; wherein the second radius of the second radiused surface is greater than the first radius of the first radiused surface; and wherein the ratio of the second radius to the first radius is at least 5:1. 15. An axle assembly for a heavy-duty vehicle, the axle assembly comprising: a central tube; an axle spindle for receiving at least one bearing assembly to support a hub for rotation relative to the axle spindle, the axle spindle fixed to the central tube, the axle spin