Genius Euro Bat, Manual

Page: 3 / 7

4
ENGLISH
EURO BAT AUTOMATION
The EURO BAT automation system for swing gates comprises an
electromechanical operator which drives the gate leaves by
means of a worm screw.
The EURO BAT operator is irreversible and locks mechanically
when the motor is not in use. Therefore a lock does not need to
be fitted.
The EURO BAT automated systems were designed and
manufactured to control access of vehicles. Avoid any other use
whatever.
1. DESCRIPTION AND TECHNICAL SPECIFICATIONS
Fig. 1
Fig. 2
1
6
2
5
3
4
Table 1: Operator technical specifications
2. STANDARD INSTALLATION LAYOUT
1) Operators
2) Photocells
3) Control unit
4) Keyswitch
5) Receiver
6) Flashing light
Notes:1) Use suitable rigid/flexible pipes for laying power cables.
2) Always keep low voltage accessory cables separate from 230V~ power
cables. To avoid interference, use separate sheaths.
Drawing A INSTALLATION DIMENSIONS
Fig. A
Fig. B
CALCULATING INSTALLATION DIMENSIONS:
GENERAL RULES
If the dimensions specified in Table A cannot be used,
calculate different dimensions as follows:
- For 90° leaf opening: a + b = c
- For leaf opening over 90°: a + b < c
- The lower the dimensions of a and b the higher the
gate speed
. Ensure that current standards are
observed.
- Make sure that the difference between a and b is
no more than 4 cm
: larger differences cause large
variations in speed during opening and closing.
- Due to the dimensions of the operator, the minimum
value for
Z is 45 mm (fig. A)
If the dimensions of the gate post or the position of
the hinge do not allow
a to be kept within the
required value, make a recess in the gate post as
shown in fig. B.
1) Motor Unit
2) Power cable
3) Worm screw
4) Front bracket
5) Rear bracket
6) Cable cover
B
A
Z
D
45 min.
L
300 mm
150 mm
100 mm
Table A: Recommended dimensions (in mm)
(¹) useful rod stroke (²) max. dimension (³) min. dimension
Model
300
400
A B C (¹) D (²) Z (³) L
α αα αα
90°
110°
90°
110°
145 145
125 125
195 195
165 165
290
290
390
390
45
45
45
45
100
80
150
120
895
895
1090
1090
l e d o M t a B o r u E
t a B o r u E
V 4 2
t a B o r u E
o t n e L
t a B o r u E
V 5 1 1
y l p p u s r e w o P
V 0 3 2
z H 0 5
c d V 4 2
V 0 3 2
z H 0 5
/ V 5 1 1
z H 0 6
r e w o p d e b r o s b A W 0 8 2 W 0 7 W 0 8 2 W 0 5 3
n w a r d t n e r r u C A 2 . 1 A 3 A 2 . 1 A 3
t u o t u c l a m r e h T C ° 0 4 1 C ° 0 4 1 C ° 0 4 1
r o ti c a p a C
F µ 8
V 0 0 4
F µ 8
V 0 0 4
F µ 5 2
V 0 5 2
. e c r o f n o it c a r t / t s u r h t . x a M N a d 0 5 3 N a d 0 0 3 N a d 0 5 3
e k o r t s d o R m m 0 0 4 / m m 0 0 3
d e e p s d o R c e s / m c 6 . 1
1 . 1
c e s / m c
5 8 . 1
c e s / m c
e g n a r e r u t a r e p m e T C ° 5 5 + C ° 0 2 +
t h g i e w r o t a r e p O g K 5 . 6
n o it c e t o r p g n i s u o H 4 4 P I
) r u o h / s e l c y c ( e l c y c y t u D 0 2 0 5 0 2 0 3
h t g n e l f a e l m u m i x a M m 4 / m 3