00198368-01_UM_SIPLACESX12-DockingStation_DE_EN_ZH.pdf - 第76页

5 Maintenance and service User manual Docking station for SIPLACE SX co mponent trolleys 5.1 Compressed air connection Edition 02/2018 76 5 Maintenance and service The docking station is almost maintenance-fr ee. Only th…

User manual Docking station for SIPLACE SX component trolleys 4 Operation

Edition 02/2018 4.4 Tearing down feeder modules

4.4 Tearing down feeder modules

To avoid unthreading the tapes manually before teardown, use the black button (item 3 in fig. 4.1

- 1, page 69). The tapes are moved back and out of the docking station.

 Cut the cover foil for the feeder modules which you want to tear down.

 Press the black button.

– Those tapes for which the cover foil has been cut will be moved back and out of the docking

station.The feeder modules can now be removed.

PLEASE NOTE

Cutting the cover foil

Only those component tapes move back and out, which have had their cover foil cut be-

forehand.

5 Maintenance and service User manual Docking station for SIPLACE SX component trolleys

5.1 Compressed air connection Edition 02/2018

5 Maintenance and service

The docking station is almost maintenance-free. Only the following tasks need to be done.

5.1 Compressed air connection

Check the correct setting of the manometer at least once a week. The possible settings can be

found in the technical data.

At the same time, check the condensation tank underneath the manometer. Empty it if water has

collected there. Since the formation of condensation depends greatly on the quality of the com-

pressed air, this interval may need to be shortened or even extended.

After starting with a weekly check, set the interval according to your needs.

Fig. 5.1 - 1 Compressed air connection

(1) Manometer

(2) Condensation tank

User manual Docking station for SIPLACE SX component trolleys 6 Circuit diagrams

Edition 02/2018 5.1 Compressed air connection

6 Circuit diagrams

O r i g . R e p l . b y .R e p l . f .

7 86543

D a t e

A u t h o r

C h e c k e d

S t a n d a r dN a m eM o d i f i c a t i o nS t a t . D a t e

S h e e t

D e s i g n e r 9

I t e m n a m e / B e n e n n u n g

o f

D o c u m e n t - N o .

D o k u m e n t e n n u m m e r

A S M A s s e m b l y S y s t e m s

G m b H & C o . K G

C o p y r i g h t r e s e r v e d

W e i t e r g a b e s o w i e V e r v i e l f a e l t i g u n g d i e s e r U n t e r l a g e , V e r w e r t u n g u n d

M i t t e i l u n g i h r e s I n h a l t s n i c h t g

e s t a t t e t , s o w e i t n i c h t a u s d r u e c k l i c h z u g e s t a n d e n .

Z u w i d e r h a n d l u n g e n v e r p f l i c h t e n z u S c h a d e n e r s a t z . A l l

e R e c h t e f u e r d e n F a l l

d e r P a t e n t e r t e i l u n g o d e r G e b r a u c h m u s t e r - E i n t r a g u n g v o r b e h a l t e n .

C o p y i n g o f t h i s

d o c u m e n t , a n d g i v i n g i t t o o t h e r s a n d t h e u s e o r

c o m m u n i c a t i o n o f t h e c o n t e n t s t h e r e o f , a r e f o r b i d d e n

w i t h o u t e x p r e s s a u t h o r i t y .

O f f e n d e r s a r e l i a b l e t o t h e p a y m e n t o f d a m a g e s . A l l r i g h t s a r e r e s e r v e d i n

t h e

e v e n t o f t h e g r a n t o f a p a t e n t o r t h e r e g i s t r a t i o n o f a u t i l i t y m o d e l o r d e s i g n .

P r i v i l e g e d b u s i n e s

s i n f o r m a t i o n .

D o n o t r e l e a s e .

E l e k t r i k S X D o c k i n g s t a t i o n 6 0

E l e c t r i c c o m p o n e n t s S X d o c k i n g u n i t 6 0

0 3 0 7 9 9 9 8 - 0 3 0 1 0 1 L X 3

1 6 . 0 9 . 2 0 0 9

T e k i n E .

L a n g e r D .

T e k i n4 0 5 2 0 5F S 0 2 1 2 . 1 0 . 1 1

T e k i n E .2 3 . 0 2 . 1 5R S 0 2 4 0 7 1 5 6

T e k i n E .2 5 . 0 1 . 1 8F S 0 3 4 0 8

2 8 4

S X - F e e d e r C o n t r o l U n i t

0 3 0 5 9 6 6 6

0 3 0 7 7 0 5 6

0 3 1 6 1 9 5 9

X 1

E n t r i e g e l u n g s l e i s t e 6 0 - f a c h 0 3 0 5 7 7 7 2

F e e d e r U n l o c k D e v i c e 6 0 - w a y

X 7

P o w e r

0 3 0 7 7 0 5 2

X 3 _ 2

X 3

X 3 X 1 3 ( X 1 ) X 1 1 ( X 1 ) X 4

( X 1 )

X 1

X 1 1 ( X 1 ) X 4

( X 1 )

S c h i e b e s c h a l t e r

S l i d e s w i t c h

S 2

0 3 0 7 7 0 5 3

S c h i e b e s c h a l t e r

S l i d e s w i t c h

S 1

C A N - B u s

X 1 3 ( X 1 )

0 3 0 9 1 7 5 4 - W 1

A d d r e s s i n g

A c h t u n g ! ! !

S c h a l t e r S 1 u n d S 2 m i t d e n K o n t a k t e n 1 b n a c h o b e n e i n b a u e n .

I n s t a l l t h e s w i t c h e s S 1 a n d S 2 w i t h t h e c o

n t a c t s 1 b u p .

1 b

1 a

S 1 _ 1 a B N + B N

S 1 _ 1 G N

S 2 _ 1 a W H + B N

S 2 _ 1 Y E

S i e h e B a u v o r s c h r i f t f ü r E r d u n g s -

a n s c h l ü s s e 9 0 0 1 0 8 5 0 - x x x x x x B D 4

D e s i g n r e q u i r e m e n t s f o r g r o u n d i n g

t e r m i n a l s 9 0 0 1 0 8 5 0 - x x x x x x B D 4 .

0 3 0 3 3 3 9 0

G r o u n d i n g c a b l e

G r u n d g e s t e l l

B a s e f r a m e

V e r k l e i d u n g

C o v e r

E n t r i e g e l u n s t a s t e r

U n l o c k s w i t c h

S 2

0 3 0 9 1 7 5 4 - W 3

0 3 0 9 1 7 5 4 - W 2

E n t r i e g e l u n s t a s t e r

U n l o c k s w i t c h

S 1

F e e d e r

X 1

X 2 1X 2 5X 2 4X 2 6X 7 X 1 1

X 1 1X 2 5X 2 4X 2 6

0 3 0 7 8 6 7 5 - W 1

0 3 0 7 8 6 7 5 - W 2

X 6

( X 1 ) X 1 0

( X 1 ) X 8

( X 1 ) X 5

( X 1 )

X 6

( X 1 ) X 1 0

( X 1 ) X 8

( X 1 ) X 5

( X 1 )

0 3 0 7 6 9 1 8

F ü r L e u c h t d r u c k t a s t e r ( S 1 ) z u r

F e e d e r - E n t r i e g e l u n g

F o r i l l u m i n a t e d p u s h b u t t o n ( S 1 ) f o r

F e e d e r - U n l o c k i n

0 3 0 7 6 4 9 9

S e n s o r

Z y l i n d e r 4

C y l i n d e r 4

0 3 0 7 6 4 9 8

S e n s o r

Z y l i n d e r 1

C y l i n d e r 1

0 3 0 7 6 9 1 7

B E - W a g e n /

C O T

3 / 2 - W e g e - M a g n e t v e n t i l

X 1 - 1 2

X 2 1

0 3 0 7 9 9 9 6

S e n s o r S 1

S e n s o r e n S 1

D e t e k t i o n

B E - W a g e n / C O T

C O T l o c k i n g

Y 1

7 4

G N Y E

B U

B K

B a s e f r a m e d o c k i n g s t a t i o n

D e s i g n r e q u i r e m e n t s f o r g r o u n d i n g

t e r m i n a l s 9 0 0 1 0 8 5 0 - x x x x x x B D 4 .

4 . I n t e r n a l t h

r e a d

P o w e r E n t r y M o d u l

C D 6 4 . 1 1 0 1 . 1 5 1

0 3 0 3 3 3 8 5

N o t e :

A d j u s t t o 2 6 . 8 V ± 0 , 5 V

P o w e r S u p p l y R S P - 5 0 0 - 2 7

0 3 1 2 1 8 0 6 - x x

A C I n p u t

G N Y E

B U

B K

G N Y E

D C O u t p u t

0 3 0 7 7 0 5 7

E l e c t r i c s u p p l y

0 3 1 4 7 2 3 8

F e e d e r - T e a r - D o w n - S u p p o r t

F e e d e r - T e a r - D o w n -

S u p p o r t

S 4

X 2 2

C o n t a c t

e l e m e n t

1 N O

P u s h b u t t o n

L a m p e n f a s s u n g ( w e i s s )

L a m p h o l d e r ( W H )

( S 2 )

F ü r L e u c h t d r u c k t a s t e r ( S 2 ) z u r

B E - W a g e n - E n t r i e g e l u n g

F o r i l l u m i n a t e d p u s h b u t t o n ( S 2 ) f o r

C O T u n l o c k i n g

L a m p e n f a s s u n g ( g r ü n )

L a m p h o l d e r ( G N )

( S 1 )

B K 5

F 1

N o t e f o r P o w e r E n t r y M o d u l e :

M i n i a t u r e F u s e , 5 x 2 0 m m ,

8 A , T i m e - L a g T , H , 2 5 0 V A C ,

U L : 1 1 5 V - 3 0 0 V D

H = High Breaking Capacity

(Ceramic Tube)

N o t e f o r W A G O -

F u s e T e r m i n a l B l o c k :

M i n i a t u r e F u s e ,

5 x 2 0 m m , 1 0 A ,

T i m e - L a g T , H ,

2 5 0 V A C ,

U L : 1 1 5 V - 3 0 0 V D C

H = H i

g h B r e a k i n g

Capacity

(Ceramic Tube)

B K 6