Machine with intermittently rotary workpiece-holding table for working and assembly of high-precision pieces

An intermittently rotary workpiece-holding table has operating units that move vertically relative to the table. The operating units are controlled by vertically swinging levers that are driven vertically at one end and at their other ends control the operating units. The levers pivot about fulcrums, each lever having two fulcrums spaced apart along its length. During a first portion of movement of the lever, that fulcrum is operative which gives the most rapid vertical movement to the operating unit. Then the first fulcrum becomes inoperative and the second fulcrum becomes operative, whereupon the speed of vertical movement of the operating unit slows, as for example for the performance of a work operation. The same pattern of movement is followed on the return stroke: first there is a relatively slow vertical movement of the operating unit in the opposite direction, followed by a relatively rapid return vertical movement, as the lever pivots successively about the two fulcrums in the reverse order of the initial operation.

This invention has as its object a intermittently rotary workpiece-holding 
table for working and assembly of high-precision pieces. 
The machine according to this invention differs from those known by the 
fact that the operating units are controlled by lever systems and not by 
cams. Much simplified kinematics a and very restrained production cost 
result. 
The machine according to this invention, which comprises operating units 
placed above, below and laterally with respect to the rotary table, is 
characterized in that the control of the advances of the operating units 
with vertical axes comes about by levers controlled by elements which in 
turn are driven by a cam having opposite profiles so as to control said 
elements in the opposite direction, the extent of the movement of said 
operating units with vertical axes is varied individually by moving the 
fulcrum of said levers. 
Also an object of this invention is a process for the efficient use of said 
machine, characterized in that, to vary the curve representing the advance 
of the work unit with respect to the angular movement of the cam, a first 
fulcrum of the levers is used in a first and last work phase and a second 
fulcrum of said levers is used in a second time. 
The accompanying drawings represent a preferred nonlimiting embodiment of 
said machine.

Shaft 6, connected to motor 7 by gears 11 and 12, controls Geneva movement 
8, 9, which transforms the continuous rotary movement into an intermittent 
movement to drive workpiece table 10. A second shaft 13 driven by motor 7 
carries a cam 5 which drives disks 2 and 2' by rollers 14, 15. 
Cam 5 exhibits two opposite profiles so that disks 2,2' are moved in 
opposite direction. 
Said disks act on levers 1, 1' which in turn control, by pawls 17, 17' (see 
also FIGS. 3 and 4), the operating units with vertical axes 18, 18'. 
Operating units 18, 18' in turn are driven by belts 19, 19' by motors 20, 
20' or can be equipped with incorporated motors. The extent of the 
advances can be varied individually for each operating unit, by moving 
fulcrums 4a, 4a'-4b, 4b' of levers 1,1'. 
For the efficient use of said machine, it is provided to vary curve 23 
(FIG. 5) which represents advance "a" of the work units, with respect to 
angular movement "s" of cam 5 (FIG. 1), according to curve 24, by using in 
a first and last work phase (AB-DE, FIG. 5) first fulcrum 4a, 4a' and in a 
second work phase (BD) a second fulcrum 4b, 4b' of said levers 1, 1', 
while the first fulcrum is removed from its support. Thus, for a constant 
speed of vertical movement of disk 2 or 2' in one direction, the pawl 17 
to 17' will have a first relatively rapid vertical movement when fulcrum 
4a or 4a' is operative and a second relatively slow vertical movement in 
the same direction when 4a or 4a' moves from the FIG. 3 to the FIG. 4 
position and 4b or 4b' becomes the operative fulcrum. For movement of 2 or 
2' in the opposite direction, the path C-D-E in FIG. 5 is followed, which 
is the reverse of path A-B-C just described.