00197498-03_UM_SiplaceCA-Serie_EN.pdf - 第148页
3 Technical Data User Manual SIPLACE CA-Series 3.7 Placement Heads From software version SC.708.0 Edition 12/2014 EN -DR AFT 148 Each DP drive which is in the low est position of the star (item 1 in fig. 3.7 - 3 ), will …
User Manual SIPLACE CA-Series 3 Technical Data
From software version SC.708.0 Edition 12/2014 EN -DRAFT 3.7 Placement Heads
147
3
Fig. 3.7 - 3 Description of functions
(1) Component pickup position, placement position, reject position, component check with com-
ponent sensor
(10) Vacuum check of the nozzle in the holding circuit, with or without component
(11) Position for optical centering of the components
Star rotation
Star axis
DP drive (segment)
Nozzle
Z axis
Check pick up, place or
reject component with
component sensor
DP axis
Each sleeve can be
rotated individually.
Component
camera for opti-
cal centering
Vacuum check
of nozzle in
holding circuit
3 Technical Data User Manual SIPLACE CA-Series
3.7 Placement Heads From software version SC.708.0 Edition 12/2014 EN -DRAFT
148
Each DP drive which is in the lowest position of the star (item 1 in fig. 3.7 - 3), will be raised or
lowered by this axis. thus picking up the components from the feeder modules and setting them
down on the PCB. In order to recognize the set-down height at the placement position a "Z axis
down" sensor is used, that recognizes a relative movement between nozzle and segment. When
the Z axis springs into position, this returns a signal - the sensor stop signal - to the axis card that
the pre-control uses to correct the position control. A pneumatic return system was implemented
to avoid the risk of a head crash when the power is switched off due to the segment being lowered
with the sleeve. This keeps the segment securely in the top position when the power is off. Irre-
spective of the pneumatic return system (item 5 in fig. 3.7 - 1
), the Z axis control is designed so
that the placement machine still has enough residual energy in the servo amplifier to move the Z
axis to the top position, in the event of a power failure. A "power fail" signal in the placement ma-
chine activates the axis card and the servo amplifier, so that the Z-axis is moved to the top posi-
tion.
The Z axis is an "intelligent axis". It "notes" the pickup height of each feeder module track and the
placement height for each component. The placement process can thus be sped up, while retain-
ing the programmed set-down force.
Star axis (item 3 in fig. 3.7 - 2) 3
The star rotates about the star axis with its 20 DP drives. This is tilted away from the vertical. A
three-phase servomotor with position control is used as the drive motor. An opto-electronic en-
coder returns information about the angle of rotation at the axis card. The actual position values
are analyzed on the axis card. The position control on the axis card provides the nominal current
and voltage values for the servo amplifier used to operate the star motor. On each DP drive there
is a nozzle that sucks up the component during the pickup process. The star transports the com-
ponent picked up from the pick/place position (item 1 in fig. 3.7 - 3
) to the optical centering position
(item 11 in fig. 3.7 - 3
) and on to the pick/place position for placement. On the way to the pickup/
placement position, the DP drive rotates the component into the required placement position.
Z-axis (item 6 in fig. 3.7 - 1) 3
The Z axis performs a vertical movement. A three-phase linear motor is used as the drive. An
opto-electronic encoder is used to measure positions. A scanner scans the positioning fiducials
on a tape measure and thus returns the position signals to the axis card.
The Z motor is operated with position control. The actual position values are analyzed on the axis
card. The position control on the axis card provides the nominal current and voltage values for the
servo amplifier used to operate the star motor.
User Manual SIPLACE CA-Series 3 Technical Data
From software version SC.708.0 Edition 12/2014 EN -DRAFT 3.7 Placement Heads
149
DP axis (item 1 in fig. 3.7 - 1) 3
The DP axis rotates the component into the required placement position, before it is centered
(item 11 in fig. 3.7 - 3
). While the component camera is recording the image, the component must
be absolutely stationary, i.e. there must be no control movements of the DP drive. Once the cor-
rection values have been determined, the DP drive turns the component into the definitive place-
ment position.
Every DP drive has its own DP motor, i.e. the nozzles can be rotated independently of one another.
The DP motor is position-controlled. Position encoders determine the actual values for the axis
motions at the axis card. The actual values are analyzed on the axis card. The position control on
the axis card provides the nominal current and voltage values for the servo amplifier used to op-
erate the DP motors.
Vacuum System 3
The vacuum system consists of two vacuum circuits - the pickup/placement circuit and the holding
circuit. These two circuits are linked to one another at the star position "pick, place, reject" (item
1 in fig. 3.7 - 3
).
The vacuum for the pickup/placement circuit is generated by a vacuum nozzle. An integrated
pressure/vacuum sensor sends the pressure and vacuum values to the control system. This con-
trol circuit allows the circuit to switch quickly and smoothly between vacuum and air kiss. Rapid
evacuation of the circuit, in turn, leads to reliable component suction, and thus increases pickup
reliability. The quick formation of an air kiss pulse for placing the component on the board in-
creases the placement speed even further.
In the holding circuit, each segment is supplied with a vacuum by a separate vacuum nozzle. The
segments are disconnected from one another, and so cannot affect one another. Even if the leak
air is taken in at one or more segments, the other segments will not be affected and can continue
placement.
The current vacuum values for a segment in the holding circuit can be measured with or without
component at the star position "vacuum check" (item 10 in fig. 3.7 - 3
).
Component Sensor (item 5 in fig. 3.7 - 2) 3
The component sensor is positioned so that the components can be measured in the pick/place
position (item 1 in fig. 3.7 - 3
). Measurements at the tip of the nozzle can thus be carried out during
every Z axis movement. Differential measurements can be used to identify components missing
from the nozzles. The component height can also be detected.