TEMIC U209B3-FP

U209B3/ U209B3–FP
TELEFUNKEN Semiconductors
Phase Control Circuit – Tacho Applications
Description:
The integrated circuit U209B3, is designed as a phase
control circuit in bipolar technology. It has also protection
circuit for the supply. Due to integration of many
functions, it leads to significant cost and space saving as
well as increased reliability. At the same time, it gives the
designer free hand to select varieties of regulators to
choose from and switching characteristics according to its
choice.
Features
Internal frequency to voltage converter
Triggering pulse typ. 155 mA
Externally controlled integrated amplifier
Internal supply voltage monitoring
Automatic soft start with minimised ”dead time”
Temperature compensated reference source
Voltage and current synchronisation
Current requirement ≤ 3 mA
Retriggering
Package: DIP14, SO16
14(16)
1(1)
Voltage / Current
detector
Automatic
retriggering
Output
pulse
4(4)
5(5)
10(10)
+
9(9)
6(6)
Control
amplifier
Phase
control unit
= f (V12)
–
3(3)
Supply
voltage
limitation
Reference
voltage
2(2)
–VS
GND
13(15)
Voltage
monitoring
Soft start
Frequency
to voltage
converter
s
11(11)
12(12)
8(8)
7(7)
95 10691
Figure 1. Block diagram – SO 16 in bracket
Rev. A1: 01.09.1995
Preliminary Information
1 (15)
Rev. A1: 01.09.1995
R 10
56 k R31
100 k
R9
47 k Preliminary Information
Actual
speed
voltage
C6
9
10
100 nF
2.2 F /16 V
C9
R 11
100 k Set speed
voltage
R8
R6
68 k C7
2.2 F
16 V
Control
amplifier
2 M
–
+
s
R7
22 k
1 nF
220 nF
8
Frequency
to voltage
converter
C5
C3
2.2 F
16 V
12
Soft start
Phase
control unit
= f (V12)
Automatic
retriggering
C8
R4
470 k
11
1
Voltage / Current
detector
14
R3
220 k 7
R5
1k
C4
220 nF
Voltage
monitoring
Reference
voltage
Supply
voltage
limitation
Output
pulse
13
220 R10
C2
3.3 nF
Speed sensor
GND C
10
C1
M
2.2 F
16 V
22 F
25 V
AEG
TW11
N600
R1
18 k
2W
R 2 680 k
2 –VS
3
6
5
4
95 10692
D1
BYT51J
N
VM =
230 V ~
L
TELEFUNKEN Semiconductors
U209B3/ U209B3–FP
Figure 2. Block diagram with typical circuitry for speed regulation
3 (15)
U209B3/U209B3–FP
TELEFUNKEN Semiconductors
Description
Mains Supply
The U209B is designed with voltage limiting and can
therefore be supplied directly from the mains. The supply
voltage between Pin 2 (+ pol/) and Pin 3 builds up
across D1 and R1 and is smoothed by C1. The value of the
series resistance can be approximated using (Figure 2):
R1 =
VM – Vs
2 IS
Further information regarding the design of the mains
supply can be found in the data sheets in the appendix.
The reference voltage source on Pin 13 of typ. –8.9 V is
derived from the supply voltage and represents the reference level of the control unit.
Operation using an externally stabilised DC voltage is not
recommended.
If the supply cannot be taken directly from the mains
because the power dissipation in R1 would be too large,
then the circuit shown in the following Figure 3 should be
employed.
~
U211B
When the potential on Pin 6 reaches the nominal value
predetermined at Pin 11, then a trigger pulse is generated
whose width tp is determined by the value of C2 (the value
of C2 and hence the pulse width can be evaluated by
assuming 8 ms/nF.
The current sensor on Pin 1 ensures that, for operation
with inductive loads, no pulse will be generated in a new
half cycle as long as current from the previous half cycle
is still flowing in the opposite direction to the supply
voltage at that instant. This makes sure that ”Gaps” in the
load current are prevented.
The control signal on Pin 11 can be in the range 0 V to
–7 V (reference point Pin 2).
If V11 = –7 V then the phase angle is at maximum = amax
i. e. the current flow angle is a minimum. The minimum
phase angle amin is when V11 = Vpin2.
Voltage Monitoring
As the voltage is built up, uncontrolled output pulses are
avoided by internal voltage surveillance. At the same
time, all of the latches in the circuit (phase control, soft
start) are reset and the soft–start capacitor is short
circuited. Used with a switching hysteresis of 300 mV,
this system guarantees defined start–up behaviour each
time the supply voltage is switched on or after short
interruptions of the mains supply.
Soft–Start
24 V~
1
R1
2
3
4
5
C1
95 10362
Figure 3. Supply voltage for high current requirements
Phase Control
The function of the phase control is largely identical to
that of the well known integrated circuit U211B. The
phase angle of the trigger pulse is derived by comparing
the ramp voltage, which is mains synchronised by the
voltage detector, with the set value on the control input
Pin 4. The slope of the ramp is determined by C2 and its
charging current. The charging current can be varied
using R2 on Pin 5. The maximum phase angle amax can
also be adjusted using R2.
4 (15)
As soon as the supply voltage builds up (t1), the integrated
soft–start is initiated. The figure below shows the
behaviour of the voltage across the soft–start capacitor
and is identical with the voltage on the phase control input
on Pin 11. This behaviour guarantees a gentle start–up for
the motor and automatically ensures the optimum run–up
time.
C3 is first charged up to the starting voltage Vo with
typically 30 mA current (t2). By then reducing the
charging current to approx. 4 mA, the slope of the charging
function is substantially reduced so that the rotational
speed of the motor only slowly increases. The charging
current then increases as the voltage across C3 increases
giving a progressively rising charging function which
more and more strongly accelerates the motor with
increasing rotational speed. The charging function
determines the acceleration up to the set–point. The
charging current can have a maximum value of 50 mA.
Preliminary Information
Rev. A1: 31.09.1995
U209B3/ U209B3–FP
TELEFUNKEN Semiconductors
95 10272
VC3
V1
2
V0
The values of C5 and C6 must be such that for the highest
possible input frequency, the maximum output voltage
does V0 does not exceed 6 V. While C5 is charging up the
Ri on Pin 8 is approx. 6 kΩ. To obtain good linearity of the
f/V converter the time constant resulting from Ri and C5
should be considerably less (1/5) than the time span of the
negative half cycle for the highest possible input
frequency. The amount of remaining ripple on the output
voltage on Pin 9 is dependent on C5, C6 and the internal
charge amplification.
∆Vo =
t
t
1
The ripple ∆Vo can be reduced by using larger values of
C6, however, the maximum conversion speed will than
also be reduced.
t
t
3
2
Gi . Vch . C5
C6
ttot
Figure 4. Soft–start
The value of this capacitor should be chosen to fit the
particular control loop where it is going to be used.
Frequency to Voltage Converter
Control Amplifier
The internal frequency to voltage converter
(f/V-converter) generates a DC signal on Pin 9 which is
proportional to the rotational speed using an AC signal
from a tacho–generator or a light beam whose frequency
is in turn dependent on the rotational speed. The high
impedance input with a switch–on threshold of typ. –
100 mV gives very reliable operation even when
relatively simple tacho–generators are employed. The
tacho-frequency is given by:
The integrated control amplifier with differential input
compares the set value (Pin 10) with the instantaneous
value on Pin 9 and generates a regulating voltage on the
output Pin 11 (together with external circuitry on Pin 12)
which always tries to hold the real voltage at the value of
the set voltages. The amplifier has a transmittance of typically 110 A/V and a bipolar current source output on Pin
11 which operates with typically ±100 A. The
amplification and frequency response are determined by
R7, C7, C8 and R8 (can be left out). For operation as a
power divider, C4, C5, R6, C6, R7, C7, C8 and R8 can be
left out. Pin 9 should be connected with Pin 11 and Pin 7
with Pin 2. The phase angle of the triggering pulse can be
adjusted using the voltage on Pin 10. An internal limiting
circuit prevents the voltage on Pin 11 from becoming
more negative than V13 + 1 V.
n
f=
60
p[Hz]
n = revolutions per minute
p = number of pulses per revolution
The converter is based on the charge pumping principle.
With each negative half wave of the input signal, a
quantity of charge determined by C5 is internally
amplified and then integrated by C6 at the converter
output on Pin 9. The conversion constant is determined
by C5, its charging voltage of Vch, R6 (Pin 9) and the
internally adjusted charge amplification Gi.
k = Gi
.
C5 . R6 . Vch
The pulse output stage is short circuit protected and can
typically deliver currents of 125 mA. For the design of
smaller triggering currents, the function IGT = f (RGT) has
been given in the data sheets in the appendix.
Automatic Retriggering
The analog output voltage is given by
= k . f.
Vo
whereas:
Vch = 6.7 V
Gi
= 8.3
Rev. A1: 01.09.1995
Pulse Output Stage
The automatic retriggering prevents half cycles without
current flow, even if the triacs is turned off earlier e.g. due
to not exactly centred collector (brush lifter) or in the
event of unsuccessful triggering. If it is necessary, another
triggering pulse is generated after a time lapse of
tPP = 4.5 tP and this is repeated until either the triac fires
or the half cycle finishes.
Preliminary Information
5 (15)
U209B3/U209B3–FP
TELEFUNKEN Semiconductors
General Hints and Explanation of Terms
To ensure safe and trouble–free operation, the following
points should be taken into consideration when circuits
are being constructed or in the design of printed circuit
boards.
The connecting lines from C2 to Pin 6 and Pin 2 should
be as short as possible, and the connection to Pin 2
should not carry any additional high current such as
the load current. When selecting C2, a low temperature coefficient is desirable.
The common (earth) connections of the set–point generator, the tacho–generator and the final interference
suppression capacitor C4 of the f/V converter should
not carry load current.
The tacho generator should be mounted without
influence by strong stray fields from the motor.
95 10716
V
Mains
Supply
p/2
p
3/2p
2p
VGT
Trigger
Pulse
tp
tpp = 4.5 tp
VL
Load
Voltage
IL
f
Load
Current
F
Figure 5. Explanation of terms in phase relationship
Absolute Maximum Ratings
Reference point Pin 2, unless otherwise specified
Parameters
Current requirement
t ≤ 10 ms
Synchronisation current
t < 10 ms
t < 10 ms
f/V converter:
Input current
t < 10 ms
Phase control:
Input voltage
Input current
Soft–start:
Input voltage
Pulse output:
Reverse voltage
Amplifier
Input voltage
Pin 8 open
Reference voltage source
Output current
Power dissipation
Storage temperature range
Junction temperature
Ambient temperature range
6 (15)
Symbol
–IS
–iS
IsyncI
IsyncV
±ii
±iv
Value
30
100
5
5
35
35
Unit
mA
Ieff
±ii
3
13
mA
–VI
±II
0 to 7
500
V
mA
Pin 12
–VI
|V13| to 0
V
Pin 4
VR
VS to 5
V
Pin 10
Pin 9
–VI
–VI
|VS|
|V13| to 0
V
Pin 13
Tamb = 45 °C
Tamb = 80 °C
Io
Ptot
7.5
570
320
–40 to +125
125
–10 to +100
Pin 3
Pin 1
Pin 14
Pin 1
Pin 14
Pin 7
mA
Pin 11
Tstg
Tj
Tamb
Preliminary Information
mA
mW
°C
Rev. A1: 31.09.1995
U209B3/ U209B3–FP
TELEFUNKEN Semiconductors
Thermal Resistance
Junction ambient
Parameters
DIP 14
SO 16: on p.c. board
SO 16: on ceramic substrate
Symbol
RthJA
Maximum
140
180
100
Unit
K/W
Electrical Characteristics
–VS = 13.0 V, Tamb = 25 °C, reference point Pin 2, unless otherwise specified
Parameters
Supply voltage for mains
operations
Supply voltage limitation
DC supply current
Reference voltage source
Temperature coefficient
Voltage monitoring
Turn–on threshold
Turn–off threshold
Phase control currents
Current synchronisation
Voltage synchronisation
Voltage limitation
Reference ramp, Figure 6
Charge current
Rϕ – reference voltage
Temperature coefficient
Output pulse
Output pulse current
Reverse current
Output pulse width
Automatic retriggering
Repetition rate
Amplifier
Common mode voltage
range
Input bias current
Input offset voltage
Output current
Short circuit forward transmittance
Rev. A1: 01.09.1995
Test Conditions / Pin
Pin 3
–IS = 3 mA
–IS = 30 mA
–VS = 13.0 V
–IL = 10 mA
–IL = 5 mA
±IL = 5 mA
Symbol
–VS
Min
13.0
Pin 3
–VS
Pin 3
Pin 13
–IS
VRef
14.6
14.7
1.1
8.6
8.3
Pin 13
Pin 3
TCVRef
Pin 1
Pin 14
Pin 1, 14
–VTON
–VTOFF
9.9
±Isyncl
±IsyncV
±Vl
0.35
0.35
1.4
Typ
2.5
8.9
11.2
10.9
1.6
Max
VLimit
Unit
V
16.6
16.8
3.0
9.2
9.1
0.5
V
mA
V
mV/K
13
V
V
2.0
2.0
1.8
mA
mA
V
20
mA
I6 = f (R5),
R5 = 1 K ... 820 kW Pin 6
a ≥ = 180 °
Pin 5,3
Pin 5
I6
1
Vϕ Ref
TCϕ Ref
1.06
1.13
0.5
1.18
V
mV/K
RV = 0, VGT = 1.2 V Pin 4
Pin 4
Pin 5,2
IO
IOR
tp
100
155
0.01
8
190
3.0
mA
mA
ms/nF
Pin 4
tpp/tp
3
4.5
6
Pin 9, 10
VICR
(V13–1V)
Pin 10
Pin 9, 10
Pin 11
Pin 11
Pin 11
IIB
VIO
–IO
+IO
Yf
I11 = f (V9/10)
75
88
Preliminary Information
0.01
10
110
120
1000
(V2–1V)
V
1
mA
mV
mA
145
165
mA/V
7 (15)
U209B3/U209B3–FP
Parameters
Test Conditions / Pin
Frequency to voltage converter
Input bias current
Pin 7
Input voltage limitation
±II = 1 mA
Pin 7
Pin 7
Turn–on threshold
Pin 7
Turn–off threshold
Pin 7
Discharge current
Figure 2
Pin 8
Charge transfer voltage
Pin 8
Charge transfer gain I9 / I8
Pin 8/9
Conversion factor
C8 = 1 nF, R9 = 100 k
Operating range f/V output Ref. point Pin 13
Pin 9
Linearity
Soft start
Figures 7 to 11
Pin 12
f/v–converter non active
Starting current
V12 = V13, V7 = V2
Final current
V12 = –0.5 V
f/v–converter active
Starting current
V12 = V13
Final current
V12 = –0.5 V
Discharge current
Restart pulse
8 (15)
TELEFUNKEN Semiconductors
Symbol
IIB
+VI
–VI
–VTON
–VTOFF
Idis
Vch
Gi
k
VO
Min
Typ
Max
Unit
0.6
2
750
8.05
150
A
mV
V
mV
mV
mA
V
660
7.25
20
6.50
7.5
100
50
0.5
6.70
8.3
5.5
0–6
±1
6.90
9.0
mV/Hz
V
%
IO
IO
20
50
30
85
50
130
A
A
IO
IO
–IO
2
30
0.5
4
55
3
6
80
10
A
A
mA
Preliminary Information
Rev. A1: 31.09.1995
U209B3/ U209B3–FP
TELEFUNKEN Semiconductors
240
10
Phase Control
Reference Point Pin 2
8
10nF
4.7nF
Soft Start
2.2nF
V13 ( V )
Phase Angle a (° )
200
160
120
6
4
Cf/t=1.5nF
80
2
f/V-Converter Non Active
Reference Point Pin 16
0
0
0
0.2
0.4
0.6
0.8
1.0
Rf ( MW )
95 10302
t=f(C3)
95 10305
Figure 6.
Figure 9.
100
10
Soft Start
Soft Start
8
V13 ( V )
I13 ( mA )
80
60
40
f/V-Converter Active
Reference Point Pin 16
6
4
20
2
f/V-Converter Non Active
Reference Point Pin 16
0
0
0
2
4
6
8
10
V13 ( V )
95 10303
t=f(C3)
95 10306
Figure 7.
Figure 10.
Soft Start
Soft Start
8
80
Reference Point Pin 16
V13 ( V )
f/V-Converter Active
Reference Point Pin 16
I13 ( mA )
95 10307
10
100
60
6
4
40
2
20
0
0
0
2
95 10304
4
6
8
10
V13 ( V )
Figure 8.
Rev. A1: 01.09.1995
t=f(C3)
Motor Standstill ( Dead Time )
Motor in Action
Figure 11.
Preliminary Information
9 (15)
U209B3/U209B3–FP
TELEFUNKEN Semiconductors
500
6
Frequency to Voltage Converter
5
250
P(R1) ( W )
Mains Supply
I8 ( A )
Reference Point Pin 2
0
4
3
2
–250
1
–500
–10
0
–8
–6
–4
–2
0
2
4
V8 ( V )
95 10308
0
3
6
9
12
15
Itot ( mA )
95 10317
Figure 12.
Figure 15.
50
100
Control Amplifier
40
Mains Supply
R 1 ( k )
I 12 ( A )
50
0
30
20
–50
10
Reference Point Pin 16
–100
0
–300
–200
–100
0
100
200
300
V10–11 ( V )
95 10309
0
4
Figure 13.
Pulse Output
5
Mains Supply
P(R1) ( W )
IGT ( mA )
16
6
80
60
40
1.4V
4
3
2
VGT=0.8V
20
1
0
0
0
200
400
600
RGT ( )
800
1000
0
95 10316
Figure 14.
10 (15)
12
Figure 16.
100
95 10313
8
Itot ( mA )
95 10315
10
20
30
40
R1 ( k )
Figure 17.
Preliminary Information
Rev. A1: 31.09.1995
U209B3/ U209B3–FP
TELEFUNKEN Semiconductors
Applications
R
33 kW
22 nF
C
L
5
C4
22 mF
10 V
100 kW
R6
3
220 kW
R3
14
D1
12
13
11
10
9
8
5
6
7
1N4004
U209B
95 10621
230 VX
M
R1
18 kW
1.5 W
1
R4
2
3
GND
4
–VS
R2
470 kW
N
470 kW
Rö
3.3 nF
C2
Cö
/t
C1
22 mF
25 V
Figure 18. Phase control (power control) for electric tools
Rev. A1: 01.09.1995
Preliminary Information
11 (15)
12 (15)
150 nF
250 V~
230 V~
95 10684
Preliminary Information
AEG
TW11N
180 W
RL
C1
R1
D1
R4
47 mF
25 V
470 kW
18 k W
1.5 W
1N4004
R2
220 k W
68 W
R15
1
14
C3
22 nF
2
GND
13
C4
3
12
–VS
5
10
470 kW
R2
4
U209B
11
10 mF
10 V
C2
Rö
C6
6
9
Cö/t
4.7 nF
100 nF
R13
7
8
R8
R7
1.5 nF
47 k W
C5
R10
56 k W
100 kW
R11
R12
R9
R14
820 W
NTC
A34–2/306
15 kW
22 kW
U209B3/U209B3–FP
TELEFUNKEN Semiconductors
Figure 19. Temperature controlled fan motor (220 Vac)
Rev. A1: 31.09.1995
Rev. A1: 01.09.1995
230 V~
95 10685
150 nF
250 V~
Preliminary Information
AEG
TW11N
180 W
RL
C1
R1
D1
47 mF
25 V
200 kW
8.2 k W
1.5 W
R4
1N4004
R2
100 kW
68 W
R15
1
14
C3
22 nF
2
13
GND
C4
3
12
–VS
5
10
470 kW
R2
4
U209B
11
10
10 V
C2
Rö
C6
6
9
Cö/t
4.7 nF
100 nF
R 13
7
8
R8
R7
1.5 nF
47 k W
C5
R10
56 k W
100 k W
R11
R12
R9
R14
820 W
NTC
A34–2/306
15 kW
22 kW
TELEFUNKEN Semiconductors
U209B3/ U209B3–FP
Figure 20. Temperature controlled fan motor (110 Vac)
13 (15)
U209B3/U209B3–FP
TELEFUNKEN Semiconductors
Design Calculations for Mains Supply
The following equations can be used for the evaluation of the series resistor R1 for worst case conditions:
R1max = 0.85
P(R1max) =
VMmin – VSmax
2 Itot
(VMmax – VSmin)2
R1min = 0.85
VM – VSmin
2 ISmax
2 R1
where:
VM
VS
Itot
= Mains voltage 220 V
= Supply voltage on Pin 4
= Total DC current requirement of the circuit
= IS + Ip + Ix
ISmax = Current requirement of the IC in mA
= Average current requirement of the triggering pulse
Ip
= Current requirement of other peripheral components
Ix
R1 can be easily evaluated from diagram figure 16 and 17
Dimensions in mm
94 9445
94 8875
14 (15)
Preliminary Information
Rev. A1: 31.09.1995
TELEFUNKEN Semiconductors
U209B3/ U209B3–FP
Ozone Depleting Substances Policy Statement
It is the policy of TEMIC TELEFUNKEN microelectronic GmbH to
1. Meet all present and future national and international statutory requirements.
2. Regularly and continuously improve the performance of our products, processes, distribution and operating systems
with respect to their impact on the health and safety of our employees and the public, as well as their impact on
the environment.
It is particular concern to control or eliminate releases of those substances into the atmosphere which are known as
ozone depleting substances ( ODSs).
The Montreal Protocol ( 1987) and its London Amendments ( 1990) intend to severely restrict the use of ODSs and
forbid their use within the next ten years. Various national and international initiatives are pressing for an earlier ban
on these substances.
TEMIC TELEFUNKEN microelectronic GmbH semiconductor division has been able to use its policy of
continuous improvements to eliminate the use of ODSs listed in the following documents.
1. Annex A, B and list of transitional substances of the Montreal Protocol and the London Amendments respectively
2 . Class I and II ozone depleting substances in the Clean Air Act Amendments of 1990 by the Environmental
Protection Agency ( EPA) in the USA
3. Council Decision 88/540/EEC and 91/690/EEC Annex A, B and C ( transitional substances ) respectively.
TEMIC can certify that our semiconductors are not manufactured with ozone depleting substances and do not contain
such substances.
We reserve the right to make changes to improve technical design and may do so without further notice.
Parameters can vary in different applications. All operating parameters must be validated for each customer
application by the customer. Should the buyer use TEMIC products for any unintended or unauthorized
application, the buyer shall indemnify TEMIC against all claims, costs, damages, and expenses, arising out of,
directly or indirectly, any claim of personal damage, injury or death associated with such unintended or
unauthorized use.
TEMIC TELEFUNKEN microelectronic GmbH, P.O.B. 3535, D-74025 Heilbronn, Germany
Telephone: 49 ( 0 ) 7131 67 2831, Fax number: 49 ( 0 ) 7131 67 2423
Rev. A1: 01.09.1995
Preliminary Information
15 (15)