Bail compensation joint for rail vehicles

The invention claimed is: 1. A bail compensating joint used in a railway vehicle braking system, said braking system including a force transfer lever and at least one force transmitting member associated with a first end of the force transfer lever for initiating a brake application comprising: a push rod associated with the force transfer lever; a ratchet associated with the push rod for rotational motion thereon; and a helical joint comprising a first bearing and a second bearing mounted on the ratchet for facilitating rotation of the ratchet, wherein the first bearing is supported by an annular inner race member and an annular outer race member, the annular inner race member having a first side seated against the ratchet and an opposing second side defining a race track for ball bearings of the first bearing, the annular outer race member having a first side engaged with the ball bearings of the first bearing to permit angular movement of the helical joint; and the second bearing is supported by an annular composite race member formed by an annular inner race member joined with an annular outer member, the composite race member supporting the second bearing with the annular inner race member thereof engaging the second bearing and defining a race track for ball bearings of the second bearing, and the annular outer member of the composite race member formed of a resiliently deformable material; and wherein the helical joint further comprises: a housing encompassing the ratchet, the helical joint, and a piston assembly, wherein the push rod comprises a solid one-piece threaded member having a first portion located outside of the housing and attached with the force transfer member and a second portion located within the housing and associated with the piston assembly, wherein actuation of the piston assembly causes the push rod to move longitudinally out of the housing and apply a force to a second end of the force transfer lever causing the force transfer lever to rotate and apply a force to the at least one force transmitting member to initiate the brake application and wherein the ratchet is threadedly connected to the second portion of the push rod. 2. The bail compensating joint of claim 1 , wherein the annular inner race member of the composite race member is metal and the annular outer member of the composite race member is rubber joined adhesively to the metal. 3. The bail compensating joint of claim 1 , wherein the first side of the outer race member supporting the first bearing comprises a tapered annular surface engaged with the ball bearings of the first bearing. 4. The bail compensating joint of claim 1 , wherein the outer race member supporting the first bearing comprises a second side having a planar surface configured for seating against an interior surface of the housing. 5. The bail compensating joint of claim 1 , wherein that the helical joint is encompassed by and positioned adjacent to a first member and a second member, wherein the annular outer member of the second bearing is seated against an inner surface of the first member and wherein the resiliently deformable material of the annular outer member permits angular movement of the helical joint relative to the first member. 6. The bail compensating joint of claim 1 , wherein the at least one force-transmitting member comprises a slack adjuster. 7. A bail compensating joint used in a railway vehicle braking system, said braking system including a force transfer lever and at least one force transmitting member associated with a first end of the force transfer lever for initiating a brake application comprising: a push rod associated with the force transfer lever; a ratchet associated with the push rod for rotational motion thereon; and a helical joint comprising a first bearing and a second bearing mounted on opposing sides of the ratchet for facilitating rotation of the ratchet, the helical joint further comprising: a pair of spherical joints disposed, respectively, on opposite sides of the ratchet, the spherical joints supporting the respective bearings; a first spherical joint of the pair of spherical joints supporting the first bearing, the first bearing supported by an annular inner race member and an annular outer race member, the annular inner race member having a first side seated against the ratchet and a second side seated against the first bearing, the annular outer race member having a first side seated against the first bearing and a second side defining a first shaped surface, the first shaped surface engaged with a second shaped surface of an annular outer member wherein the first shaped surface and second shaped surface are complementary shapes with respect to one another; and a second spherical joint of the pair of spherical joints supporting the second bearing, the second bearing supported by an annular inner race member and an annular outer race member, the annular inner race member of the second spherical joint has a first side seated against the ratchet and a second side seated against the second bearing, the annular outer race member of the second spherical joint has a first side seated against the second bearing and a second side defining a third shaped surface, the third shaped surface engaged with a fourth shaped surface on an annular outer member of the second spherical joint wherein the third shaped surface and fourth shaped surface are complementary shapes with respect to one another; and a housing encompassing the ratchet, the helical joint, and a piston assembly, wherein the push rod comprises a solid one-piece threaded member having a first portion located outside of the housing and attached with the force transfer member and a second portion located within the housing and associated with the piston assembly, wherein actuation of the piston assembly causes the push rod to move longitudinally out of the housing and apply a force to a second end of the force transfer lever causing the force transfer lever to rotate and apply a force to the at least one force transmitting member to initiate the brake application and wherein the ratchet is threadedly connected to the second portion of the push rod. 8. The bail compensating joint of claim 7 , wherein the first shaped surface is a concave-shaped surface and the second shaped surface is a convex-shaped surface and the annular outer race member of the first spherical joint is engaged with the annular outer member of the first spherical joint in a male-female relationship. 9. The bail compensating joint of claim 7 , wherein the third shaped surface is a convex-shaped surface and the fourth shaped surface is a concave-shaped surface and the annular outer race member of the second spherical joint is engaged with the annular outer member of the second spherical joint in a female-male relationship. 10. The bail compensating joint of claim 7 , wherein the second spherical joint is a mirror image of the first spherical joint. 11. The bail compensating joint of claim 7 , wherein the second side of the annular inner race member of the first spherical joint defines a race track for ball bearings of the first bearing. 12. The bail compensating joint of claim 7 , wherein the first side of the annular outer race member of the first spherical joint defines a race track for ball bearings of the first bearing. 13. The bail compensating joint of claim 7 , wherein the annular outer member of the first spherical joint has a first side defining the convex-shaped surface and a second, planar side. 14. The bail compensating joint of claim 7 , wherein the second side of the annular inner race member of the second sp