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Электронный компонент: U2100B-xFPG3

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U2100B
Rev. A3, 15-Jan-01
1 (8)
Timer Control for Triac and Relay
Description
The timer control circuit U2100B uses bipolar technol-
ogy. It has different mode selections (zero voltage switch,
phase control, relay control). The output stage is triggered
according to input conditions. It can be used in triac ap-
plication for two- or three-wire system as a power switch.
Features
D Adjustable and retriggerable tracking time
D Window monitoring for sensor input
D Enable input for triggering
D Internal noise suppression (40 ms) and retrigger
blocking (640 ms)
D Two- or three-wire applications
Applications
D Motion detectors
D Touch sensors
D Timer
Block Diagram
V
mains
Supply voltage
limitation
Voltage control
monitoring
Noise
suppression
40 ms
Retrigger
delay
640 ms
Mode
Sync
Control
logic
Trigger
window
+
+
V
Ref
0.65 V
Ref
0.6 V
Ref
ON
0.5 V
Ref
OFF
RC Oscillator
Divider 1:2
10
7
0.5 V
Ref
En-
able
C
t
R
t
5
6
Trigger
signal
C
2
8
C
1
R
1
R
sync
D
1
2
V
S
4
R
G
3
1
Output
GND
L
N
Load
selection
Z
Figure 1. Block diagram with external circuit
Ordering Information
Extended Type Number
Package
Remarks
U2100B-x
DIP8
Tube
U2100B-xFP
SO8
Tube
U2100B-xFPG3
SO8
Taped and reeled
U2100B
Rev. A3, 15-Jan-01
2 (8)
Pin Description
1
2
3
4
8
7
6
5
GND
V
S
Output
Sync
V
Ref
Osc
TRIG
EN
U2100B
Figure 2. Pinning
Pin
Symbol
Function
1
GND
Reference point
2
V
S
Supply voltage
3
Output
Driver output
4
Sync
Synchronisation and mode selection
5
EN
Enable
6
TRIG
Input trigger signal
7
Osc
RC Oscillator
8
V
Ref
Reference voltage
General Description
The monostable integrated power-control circuit
U2100B can be used according to the mode selection in
relay or triac applications. Beyond that, it can be used in
triac applications for two-wire system as power switch
(the load in series to the switch), where the supply voltage
for the control unit is gained from phase rest angle
(
a
min
-operation).
Control
L
N
Figure 3. Two-wire circuit
Control
L
N
Figure 4. Three-wire circuit
For three-wire switch systems, two operation modes are
possible:
Zero voltage switch operation for triac control
Static operation for relay control
Mode Selection Pin 4 and Supply Voltage
Pin 2
Operation modes can be selected by the external voltage
at the sync. input Pin 4 (clamping). Mode selection deter-
mines the current requirement of the relay's or triac's
driver stage and hence the selection of supply voltage.
Zero Voltage Switch Operation (Figure 5)
Selection condition:
V
4
= internal sync. limitation, without external clamping
R
1
[ 0.85
V
M
V
S
2 I
tot
I
tot
= I
S
+ I
p
+ I
X
where:
I
S
= Supply current of IC without load
I
P
= Average trigger current I
G
I
X
= External circuit current requirement
V
M
= Mains voltage
Required firing pulse width t
p
t
p
+ 2warcsin
I
L
V
M
P
2
where:
I
L
= Triac latching current
P
= Power at load Z
R
sync
[k
W] [
V
M
[V]
2 sin w t
p
[s] 0.7
1.8
10
2
176
U2100B
Rev. A3, 15-Jan-01
3 (8)
2
V
S
4
Sync
R
sync
R
G
3
Output
C
1
D
1
R
1
I
G
Z
1
L
N
V
M
GND
Figure 5. Zero voltage switch operation
DC Operation (Figure 6)
Selection condition:
+V
4
= 6.1 V V
4
= int. limitation
whereas:
R
0
[ 1 10 X
c
X
c
+ 0.85
V
M
V
S
I
tot
I
tot
+ I
S
) I
Rel
) I
X
C
0
+
1
w X
C
2
V
S
R
sync
3
Output
C
1
I
Rel
1
GND
BZX85C22V
4
Sync
C
o
R
o
Rel
N
L
V
M
230 V~
4xBYX86
Figure 6. DC operation
a
min
-Operation (Figure 7)
Selection condition:
V
4
= 6.5 to 7.8 V
+V
4
= int. limitation
R
amax
+ R
sync
3.6 V
V
R(peak)
3.6 V
R
amin
+ R
sync
10 V
V
M
2 10 V
V
R(peak)
is the peak voltage of the rest phase angle, which
should be high enough to generate the supply voltage, V
S
.
I
G
V
R(peak)
BZX85
C22V
N
V
M
230 V~
2
V
S
4
Sync
R
sync
R
G
3
Output
C
1
Z
1
GND
L
C
o
R
o
1N4148
BZX55
6V8
R
a
D
1
IN 4007
Figure 7.
a
min
operation (two wire operation)
C
1
=
100
mF/35 V
C
o
=
0.33
mF/250 V
R
o
=
390
W
R
sync
=
220 k
W
R
a
=
10 k
W
R
G
=
390
W
D
1
=
IN 4007
U2100B
Rev. A3, 15-Jan-01
4 (8)
Tracking Time Pin 7
An internal RC oscillator with following divider stage
1:2
10
allows a very long and reproducible tracking time.
RC-values for required final time, t
t
, can be calculated as
follows:
R
t
[
W] +
t
t
[s]
10
6
1.6
1024 C
t
[
mF]
C
t
[
mF] +
t
t
[s]
10
6
1.6
1024 R
t
[
W]
t
t
[s]
+
C
t
[
mF] R
t
[
W] 1.6 1024
10
6
Trigger Inputs Pins 5 and 6 (Figures 8, 9)
Two AND-connected, identical inputs determine the
trigger conditions of the monostable time stages, i.e., both
inputs must be in position "ON" so that the output is
switched ON. The tracking time starts after the trigger
conditions has elapsed. The output ON state is given until
the tracking time is over.
Input Pin 5 is a simple comparator whereas input Pin 6 is
built up as a window discriminator.
The noise suppression for t
ON
= 40 ms guarantees that
there are no peak noise signals at the inputs which could
trigger the circuit.
At the same time, the retrigger is delayed for a duration
of 640 ms (t
OFF
), to avoid noise signal to trigger the relay.
0
Hysteresis
OFF
ON
T
1
= 0.5 V
Ref
T
2
= 0.65 V
Ref
V
Ref
V
5
Figure 8. Trigger condition, Pin 5
0
ON
T
1
+ 0.5 V
Ref
T
2
+ 0.65 V
Ref
V
Ref
V
6
ON
OFF
Figure 9. Trigger condition, Pin 6
Absolute Maximum Ratings
Reference point Pin 1, unless otherwise specified
Parameters
Symbol
Value
Unit
Supply
Pin 2
Supply current
Peak current
t
10
ms
I
S
i
s
10
60
mA
mA
Supply voltage
V
S
32
V
Reference voltage source
Pin 8
Output current
I
O
3
mA
Synchronization
Pin 4
Input current
t
10
ms
I
Sync.
i
Sync.
5
20
mA
mA
Window monitoring
Input voltage
Pin 6
V
1
V
Ref
to 0
V
Enable Schmitt trigger
Pin 5
Input voltage
V
1
V
Ref
to 0
V
Driver output
Pin 3
Collector voltage
V
o
V
S
to 2
V
Storage temperature range
T
stg
40 to +125
C
Junction temperature
T
j
125
C
Ambient temperature range
T
amb
0 to 100
C
U2100B
Rev. A3, 15-Jan-01
5 (8)
Thermal Resistance
Parameters
Symbol
Value
Unit
Junction ambient
DIP8
SO8 on PC board
SO8 on ceramic
R
thJA
R
thJA
R
thJA
110
220
140
K/W
K/W
K/W
Electrical Characteristics
V
S
= 18 V, T
amb
= 25
C, reference point Pin 1, unless otherwise specified
Parameters
Test Conditions / Pins
Symbol
Min
Typ
Max
Unit
Supply-voltage limitation I
S
= 800
mA
Pin 2
I
S
= 2 mA
V
S
V
S
21
21.3
23
24
V
V
Current consumption
I
3
= 0
I
S
750
mA
Supply-voltage monitoring
Pin 2
ON-Threshold
V
S
15
V
OFF-Threshold
V
S
6.5
V
Reference voltage
I
8
= 0.1 mA
Pin 8
I
8
= 1.5 mA
V
Ref
V
Ref
4.75
4.55
5.25
5.25
V
V
Synchronization
Pin 4
Input current
i
sync
0.1
1.1
mA
Voltage limitation
I
4
=
1 mA
V
sync
8.8
9.4
10
V
Rest phase angle
a
min
-threshold
ON
Off
V
T
V
T
3.6
1.8
4
2
4.4
2.2
V
V
Zero-identification
Pin 4
Zero-identification
ON
OFF
V
T
I
T
V
T
I
T
1.5
8.5
4
20
V
mA
V
mA
Operation selection
Pin 4
Zero voltage switch
V
sync
V
4
limit
a
min
-operation
+V
sync
V
sync
V
4
limit
6.5 to 7.8
V
V
DC mode
V
sync
+V
sync
V
4
limit
6.5 to 7.8
V
V
Window monitoring figure 9
Pin 6
Threshold 1
V
I
/V
Ref
0.52
0.49
0.46
Threshold 2
V
I
/V
Ref
0.67
0.65
0.63
Enable Schmitt trigger, figure 8
Pin 5
Threshold 1
OFF
V
I
/V
Ref
0.33
0.3
0.27
Threshold 2
ON
V
I
/V
Ref
0.62
0.6
0.58
Oscillator
f
+
1
1.6
R
t
C
t
Threshold 1
Pin 7 1
V
I
/V
Ref
0.25
0.20
0.15
Threshold 2
Pin 7 8
V
I
100
200
mV
Input current
Pin 7
I
I
100
500
nA
Output stage limiter diode
Pin 3
Saturation voltage
I
3
= 100 mA
V
32
2
V
Output current
I
3
100
mA