IL9010N, IL9010D
Korzhenevskogo 12, Minsk, 220108, Republic of
Belarus
Fax: +375 (17) 278 28 22,
Phone: +375 (17) 278 07 11, 212 24 70, 212 24 61,
212 69 16
E-mail: office@bms.by
URL: www.bms.by
IC of collector electric motor controller
Microcircuit is designed for stabilization of collector electric motor rotation speed. IC`s supply
power can be obtained from alternating current line with voltage 110 V or 220 V, frequency of 50
Hz or 60 Hz through half-wave rectifier and ballast resistor.
Functions:
Microcircuit enables stabilization of electric motor speed ,
optimal triac firing (2nd and 3rd quadrants ), repetitive trigger
pulses when triac current is interrapted by motor collector,
changing of triac current at work with induced load, soft start ,
power failure detection and general circuit reset .
T
A
= 0
o
C +70
o
C
Features:
Circuit power supply obtained from AC net
Can be used in with AC networks 220 V / 50 Hz and 110
V / 60 Hz
Low count and cost of external components
Optimal triac firing (2
nd
and 3
nd
quadrants)
Repetitive control pulses when current interrupted by
electric motor collector
Tracing triac current while operating for inductive load
Possibility of Soft start mode setting
Power error detection and general reset
Embedded voltage comparator for expansion of circuit
control functions
Low bias input current at comparator`s inputs: 100nA
Low shift current at comparator`s inputs
10nA
Damper of electrostatic dischargeat comparator inputs
increase circuit reliability
Low power consumption
Symbols for pins in package
1
2
3
4
5
6
7
14
13
12
11
10
9
8
- Input
+ Input
Soft Start
Phase Angle Set
Feedback Input
Integration Cap
Current Programming
Output
Vcc
Vee
Gate Trigger Pulse
Ramp Generator
Current Sense
Voltage Sense
Stabilization of electric motor rotation speed is provided by integrated positive feedback on current.
IL9010N generates triac control pulses and provides stabilization of collector motor speed without tacho
generator.
Voltage comparator ensures control of basic circuit reset. While voltage levels coincidence, signal is
generating at comparator inputs (inputs 13, 14) and shifts control circuit from Permitted state to the
Prohibited state, in a similar way, as circuit state is changing while supply voltage low level. At that, circuit
becomes insensitive to the supply voltage variation (circuit of supply voltage variation control is blocked by
the signal from comparator output).
IL9010N
Korzhenevskogo 12, Minsk, 220108, Republic of
Belarus
Fax: +375 (17) 278 28 22,
Phone: +375 (17) 278 07 11, 212 24 70, 212 24 61,
212 69 16
E-mail: office@bms.by
URL: www.bms.by
Maximum ratings.
Symbol Parameter
designation Min Max
Measuring
unit
U
pin
Maximum voltage,
On outputs 5,8,12-U
5
,U
8
,U
12
On output 04-U
4
-Ucc
-3.0
0
3.0
V
U
pin11
Maximum positive voltage at 11-U
11
output
-
0
V
U
pin3
Maximum positive voltage at 03-U
3
output
-
0.5
V
I
pin
Maximum current
At output 03- I
3
At outputs 06 and 07 - I
6
, I
7
At output 09 - I
9
-20
-2,0
-0,5
+20
+2,0
+0,5
mA
I
pin
Maximum current,
At output 10 - I
10
At output 11 - I
11
+300
-500
-300
-
mcA
U
IDR
Input differential voltage range
(outputs 13. 14)
-Ucc 0 V
I
SC
Output current of short circuit (output
01) relatively 02 output (Ucc)
1
Constant
mA
P
D
Maximum dissipated power (amb=25
)
-
250 mWt
Tstg
Storage temperature range
-60
+125
Rt j-a
Maximum temperature resistance
chip -- environment
- 100
/Wt
1 - Maximum output current (output 01) can obtain 20mA, not depending on power supply value. Shorted
output circuits can cause over heat and, finally, destruction.
Tolerable ratings.
Symbol
Parameter designation
Min Max
Measuring
unit
Operation environment temperature range
0
+70
Rt j-a
Maximum temperature resistance chip --
environment
- 100
/Wt
IL9010N, IL9010D
Korzhenevskogo 12, Minsk, 220108, Republic of
Belarus
Fax: +375 (17) 278 28 22,
Phone: +375 (17) 278 07 11, 212 24 70, 212 24 61,
212 69 16
E-mail: office@bms.by
URL: www.bms.by
Electrical characteristics:
T
A
= 25 C; (unless specified otherwise)
Symbo
l
Parameter designation
Measuring mode
Norm Unit
Min
Max
1 2
3
4
5
6
I
3
= -2.0 mA
|-7.6|
|-9.6|
-Ucc Internal
stabilizer
voltage
(output 03)
I
3
= -2.0 mA; 0
o
C
T
A
70
o
C
|-6.08| |-11.52|
V
U
3
=-6.0 V; I
4
=0 - |-2.5|
-Icc Consumption
current
U
3
=-6.0 V; I
4
=0 ;
0
o
C
T
A
70
o
C
- |-3.0|
mA
-
|-Ucc +0.2|
|-Ucc +0.5|
U
3EN
Control enable voltage
0
o
C
T
A
70
o
C
|-Ucc +0.18|
|-Ucc +0.55|
V
- |-
U
3EN
+0.12|
|- U
3EN
+0.5|
U
3DIS
Control disable voltage, V
0
o
C
T
A
70
o
C
|- U
3EN
+0.11|
|- U
3EN
+0.55|
V
- -
-200
I
11
Input
current
of output offset
11
0
o
C
T
A
70
o
C
-240
nA
- 1.2
2.0
U
8-11
Static bias of control voltage
0.96
2.4
V
R
10
=100 kOhm;
-Ucc
U
12
-3 V
-11 -17
I
12
Soft start capacitor charging
current
R
10
=100 kOhm;
-Ucc
U
12
-3 V;
0
o
C <T
A
<70
o
C
-8.8 -20.4
mkA
R
10
=100 kOhm,
-2 V
U
5
-
6 V
60 80
I
5P
Sawtooth generator capacitor
discharge current
R
10
=100 kOhm,
-2 V <
U
5
<
-6 V;
0
o
C <T
A
<70
o
C
53 88
mkA
- -1.5
-10
I
5
Sawtooth generator capacitor
charging current
0
o
C
T
A
70
o
C
-1.2 -12
mA
- |-1.0|
|-2.5|
U
5
Sawtooth high voltage
0
o
C
T
A
70
o
C
|-0.8| |-3.0|
V
- 1.0
1.5
U
10
Programming output voltage
relativ to output 1
0
o
C
T
A
70
o
C
0.8 1.8
V
U
4
=0 V
60
80
I
4
Output current (incoming), mA
U
4
=0 V; 0
o
C
T
A
70
o
C
48 96
mA
U
4
=2.0 V
-
4.0
I
4L
Output leakage current
U
4
=2.0 V; 0
o
C
T
A
70
o
C
4.8
mkA
- -40
40
Isync
Threshold level of current
synchronization I
6 ,
I
7,
0
o
C
T
A
70
o
C
-48 48
mkA
- |-5.6|
|-8.5|
U
LTH
Minimum low sawtooth voltage
(output 05)
0
o
C
T
A
70
o
C
|-5.0| |-9.35|
V
U
9
= 0 V
1.6 x I
5P
2.4xI
5P
I
9
Input current of output offset of
09 output
U
9
= 0 V; 0
o
C
T
A
70
o
C
1.4 x I
5P
2.6
xI
5P
-
R
10
=100 kOhm;
U
9
=50mV
50 90
R
10
=100 kOhm;
U
9
=50mV;
0
o
C
T
A
70
o
C
45 99
R
10
=270 kOhm;
U
9
=50mV
28.8 50
A
Transfer function amplification
coefficient,
U
8
/
U
9
R
10
=270 kOhm;
U
9
=50mV;
0
o
C
T
A
70
o
C
25.9 55
-
U
9
= 0 V
50
450
Uoff
Residual bias on 05-08 ouputs
U
9
= 0 V; 0
o
C
T
A
70
o
C
0 500
V
U
9
= 0,1 V
96
180
Z
8
Full internal resistance of 08
output
U
9
= 0,1 V; 0
o
C
T
A
70
o
C
76.8 215
kOh
m
tp
Output pulses duration
C
5
=47 nF; R
10
=270
kOhm
30 80 mcs
IL9010N
Korzhenevskogo 12, Minsk, 220108, Republic of
Belarus
Fax: +375 (17) 278 28 22,
Phone: +375 (17) 278 07 11, 212 24 70, 212 24 61,
212 69 16
E-mail: office@bms.by
URL: www.bms.by
Symbo
l
Parameter designation
Measuring mode
Norm Unit
Min
Max
1 2
3
4
5
6
C
5
=47 nF; R
10
=270 kOhm
0
o
C
T
A
70
o
C
24 96
C
5
=47 nF; R
10
=270 kOhm
120
510
t
Repetition period of output
pulses
C
5
=47 nF; R
10
=270 kOhm;
0
o
C
T
A
70
o
C
96 612
mks
R
10
=100 kOhm; Note 2
-
|
5,0|
U
I0
Input voltage of zero bias
(outputs 13,14)
R
10
=100 kOhm; Note 2;
0
o
C
T
A
70
o
C
mV
R
10
=100 kOhm; Note 2, 3
-
-250
I
IB
Input offset current (outputs
13, 14)
R
10
=100 kOhm; Note 2, 3;
0
o
C
T
A
70
o
C
-400
nA
R
10
=100 kOhm; Note 2
-
|
50|
I
I0
Input
currents
difference
(outputs 13, 14)
R
10
=100 kOhm; Note 2;
0
o
C
T
A
70
o
C
|
150|
nA
R
10
=100 kOhm; I
01
=-4 mcA;
U
14
=-Ucc+1,0 V; U
13
=-Ucc
- -Ucc
+0,4
U
OL
Output
saturation
voltage
(output 01)
R
10
=100 kOhm; I
01
=-4 mcA;
U
14
=-Ucc+1,0 V; U
13
=-Ucc;
0
o
C
T
A
70
o
C
- -Ucc
+0,7
mV
I
OL
Output
leakage
current (output
01)
R
10
=100 kOhm;
U
13
=-Ucc+1,5 V; U
14
=-Ucc
0
o
C
T
A
70
o
C
- -1,0
mcA
Notes
1. Norm for electrical parameters are given for following conditions: environment temperature -- +25
;
voltage is related to output 02 General, unless other specified.
2. Bias current on comparator`s inputs of voltage comparator (outputs 13, 14), I
IB
, n, is outcoming (input
cascades on outputs 13, 14 are performed on p-n-p transistors). This current is practically independent
from supply voltage.
3. Measurements are implementing in switching point of voltage comparator (output 01); U
01
=-Ucc+1.5V,
R
13
, R
14
100 , over all range of input voltage of in-phase signal U
ICRmax
-Ucc 1.5 V (outputs 13,
14).
4.
U
H
, U
L
parameters determine working capacity of internal control line of supply voltage tracing
Positional resistor designations, given in the table, related to corresponding circuit outputs (for example,
R10 on output- 10), but not to standard switching circuit
.
IL9010N, IL9010D
Korzhenevskogo 12, Minsk, 220108, Republic of
Belarus
Fax: +375 (17) 278 28 22,
Phone: +375 (17) 278 07 11, 212 24 70, 212 24 61,
212 69 16
E-mail: office@bms.by
URL: www.bms.by
Standard circuit of IC switching on.
DA1
M
R8
R9
R10
C1
C4
C5
C6
R13
R16
VD5
VS1
M1
~220
03
07
06
04
09
02
12
08
10
05
11
01
13
t
o
14
R2
R3
R4
R5
R6
R7
R11
R12
R14
R15
R17
VD3
VD4
C2
C3
R18
VD1
VD2
R1
Figure 1 - Standard circuit of switching on IL9010N IC in circuit of commutator electric motor
control and protection of motor from load current exceeding
Supple voltage
stabilizer
firing generator
Ramp
oscillator
Main
comparator
Soft start control
circuit
Supply
voltage
tracing circuit
phase angle pin
set
circuit of current
synchronization
Circuit of
voltage
synchronizatin
12
10
05
07
06
04
02
03
09
08
11
Voltage
comparator
13
14
01
Figure 2 - Schematics of IL9010N IC
Functional description.
At fig. 1 is standard connection circuit of IL9010N IC in collector electric motor control circuit
and motor protection from load current exceeding. In addition, circuit provides protection from
motor overheat (resistor R3).
Motor protection from load current exceeding is implementing through protection circuit,
performed on elements R1, R2, R4 - R7, R17, VD1 - VD3, outputs 13 (direct input of voltage
comparator), 14 (inverting input of voltage comparator), 01 (voltage comparator output) of
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