Bendix Commercial Vehicle Systems COMPACT 500 9/87 User Manual

3

FIGURE 1 - MECHANICAL OPERATION

BALL SCREW

RECIRCULATING

BALLS

PISTON NUT

STEERING

WHEEL

SPINDLE

PITMAN

ARM

POWER CYLINDER

PITMAN ARM

PISTON NUT

RECIRCULATING

BALLS

LEFT TURN

RIGHT TURN

a screw and nut through the action of the chain of

recirculating balls that serve as an interface. Rotation of

the ball screw causes axial movement of the piston within

the power cylinder. Gear teeth cut directly into the piston
mesh with corresponding sector gear teeth on the output

shaft and as the piston moves, the output shaft and attached

pitman arm are rotated.

HYDRAULIC OPERATION

The driven end of the ball screw rotates on a ball bearing
contained in the valve body. Hydraulic pressure enters and

exits the power steering gear through lines connected to

threaded ports in the valve body. A pressure relief valve
contained in the valve body prevents overpressurization of

the power steering gear.

Hydraulic pressure in excess of the setting of the relief valve
causes the valve to open a channel to the reservoir return

side of the gear.

The ball screw assembly is retained in the valve housing by
a valve nut which forms the outermost element of the rotary

control valve. The valve nut contains circular channels and

radial passages which serve to direct hydraulic oil into and
out of the rotary control valve. The ball screw assembly forms

the rotary control and consists of three parts; the input shaft,

torsion bar, and ball screw.

One end of the input shaft is finely splined for connection to

the steering column while the other end has a coarse spline

which fits loosely with a similar spline inside the worm screw.

The coarse splines form mechanical stops which limit the

amount of relative rotation between the ball screw and input

shaft. A torsion bar connects the input shaft to the ball screw.
Six evenly distributed longitudinal grooves are machined into

the outer surface of the input shaft and correspond to six

grooves machined into the bore of the ball screw. Holes
extend from the outside surface of the ball screw into the

six grooves in the bore. These holes allow pressurized oil to

enter and exit the two inner elements of the rotary control
valve. The six grooves in the bore of the ball screw are

connected alternately to each side of the piston through

three pairs of the drilled holes. The other three holes admit
pressurized oil directly to three of the six grooves in the

input shaft. The other three grooves in the output shaft carry

oil to the return line connection. The length of the six pairs
of grooves cut into the ball screw and input shaft allows

large pressure changes to be achieved with a small rotational

displacement of the valve elements.

The rotary control valve is an open center type which allows

a continuous flow of oil (through the longitudinal grooves in

the input shaft and bore of the ball screw) when held in the
neutral position by the torsion bar. The large porting of the

valve design allows neutral position operating pressure to

remain in the 40-65 psi range which results in reduced
hydraulic pump power consumption and lower oil

temperatures.

When steering effort is applied, the input shaft and ball screw
tend to turn in unison however the spring action of the torsion