SiplaceX4_en - 第105页

1 - 5 S tudent Guide SIPLACE X Edition 09/2005 3 Communication and Control 5 3.4 Axis control 3.4.1 Position measuring system 3.4.1.1 T rack signals and Zero pulse signal Our Axes systems cons ists of the following parts…

1 - 28

Student Guide SIPLACE X

3 Communication and Control Edition 09/2005

3.3.13 Communication X-Feeder

The Communication between the Feeder Control unit (FCU) and each X- Feeder is carried out via

a CAN bus. This CAN bus is only responsible for the communication between FCU and X-Feeder

and machines CAN bus controlled the "Feeder Can Bus".

Fig. 3.3 - 23 Communication X-Feeder

The data and power supply from the FCU to each feeder is contactless.

SIPLACE

X-Serie

Feeder

Feeder-CAN Bus

BE-Wagen

(COT)

Power Data

Machine CAN Bus

FCU Location 1

FCU Location 2

FCU Location 3FCU Location 4

1 - 5

Student Guide SIPLACE X

Edition 09/2005 3 Communication and Control

3.4 Axis control

3.4.1 Position measuring system

3.4.1.1 Track signals and Zero pulse signal

Our Axes systems consists of the following parts.

– Axis controller board with VC 3 Controller

– Servo amplifier

– Motor

– Position measuring system with Incremental- scale and -encoder

Fig. 3.4 - 1 Principle circuit for position measuring systems

Legend

The closed-loop control system of an axis is detecting the position directly at the moving element

of the axis. The position measuring system generates an analoge signal when the encoder moves

over the scale. By standard an amplifier, a multiplication circuit and digitalization is integrated in

the encoder case. A test connector is normally available at the next interface board, or the digital

signals are measurable at the Track A / B and Zero pulse output of the SIPLACE Axis Tester.

At the HFand Siplace X machine the track signals are the only feedback from the Axis to the con-

trol unit. This means any fault on the track signals may influence the Axis control; the Gantry axes

immediately stops at a fault; the head axes finish the positioning to target before showing a track

signal error.

(1) Incremental scale with zero pulses (2) Incremental encoder for track A / B and Zeropulse

signals (O-pulse.)

(3) Analoge signal output and amplifier (4) Electronic signal multiplication and signal digita-

lization

(5) Test output digital signals (6) Axis controller

A /A

B /B

0 -impuls .

/0-im

uls .

0 -impuls

1 - 6

Student Guide SIPLACE X

3 Communication and Control Edition 09/2005

The position is determined by a position counter on the axis controller. The moving direction of the

axis is determined by the phase shift of the Tracksignals (a leading Track A signal means moving

to the right; a leading Track B signal means moving to the left).

To make the encoder system robust for the high resolution we multiply the frequency of the ana-

loge signal and create a high resolution digital measuring system.

Fig. 3.4 - 2 Principle signal multiplication at analog Track signals of a gantry axis

Legend

In principle the track signal is multiplied by a ’Schmitt Trigger’ circuit. By comparing analoge and

digital signals on our axes you will find a multiplication by 25 (see Fig. 3.4 - 2), 10 or by 1.

The track signals of the C&P head axes can only be measured as digital signals i.e. the transfor-

mation of the analogue track signals into digital track signals occurs directly in the incremental en-

coder without any Test connector in that encoder case.

(1) Analoge track A signal Incremental

encoder

(2) Analoge track B signal Incremental

encoder

(3) Digital track A signal at Test connector (4) Digital track B signal at Test connector

(5) Period time of analoge track signal (6) Period time of digital track signal