STMICROELECTRONICS TN22

TN22
®
Application Specific Discretes
A.S.D.™
STARTLIGHT
n
n
n
1
2, TAB
FEATURES
3
High clamping voltage structure (1200 - 1500V)
Low gate triggering current for direct drive from
line (< 1.5mA)
High holding current (> 175mA), ensuring high
striking energy.
TAB
TAB
1
DESCRIPTION
The TN22 has been specifically developed for use
in electronic starter circuits. Use in conjunction
with a sensitive SCR and a resistor, it provides
high energy striking characteristics with low triggering power. Thanks to its electronic concept, this
TN22 based starter offers high reliability levels and
extended life time of the fluorescent tubelamps.
2
3
1
2
3
DPAK
(TN22-B)
IPAK
(TN22-H)
ABSOLUTE RATINGS (limiting values)
Symbol
Parameter
Value
Unit
Tj = 110°C
400
V
VDRM
Repetitive peak off-state voltage
IT(RMS)
RMS on-state current
Full sine ware (180° conduction angle)
Tc= 95°C
2
A
IT(AV)
Mean on-state current
Full sine ware (180° conduction angle)
Tc= 95°C
1.8
A
ITSM
Non repetitive surge peak on-state current
(Tj initial = 25°C)
tp = 8.3ms
22
A
tp = 10ms
20
tp = 10ms
2
A 2s
50
A/µs
- 40 to + 150
- 40 to + 110
°C
260
°C
I2t
I2t Value for fusing
dI/dt
Critical rate of rise of on-state current
IG = 5 mA
dIG /dt = 70 mA/µs.
Tstg
Tj
Storage and operating junction temperature range
Tl
Maximum lead temperature for soldering during 10s at
4.5mm from case
October 2000 - Ed:1
1/7
TN22
THERMAL RESISTANCES
Symbol
Parameters
Value
Unit
100
°C/W
3
°C/W
Type
Value
Unit
Tj= 25°C
MAX
1.5
mA
VD=12V (DC) RL=33Ω
RGK = 1 KΩ
Tj= 25°C
MAX
3
V
VGK = 0V
Tj= 25°C
MIN
175
mA
VTM
ITM= 2A tp= 380µs
Tj= 25°C
MAX
3.1
V
IDRM
VDRM Rated
Tj= 25°C
MAX
0.1
mA
dV/dt
Linear slope up to
VD=67%VDRM VGK = 0V
Tj= 110°C
MIN
500
V/µs
Rth(j-a)
Junction to ambient
Rth(j-c)
Junction to case
GATE CHARACTERISTICS (maximum values)
PG (AV)= 300 mW PGM = 2 W (tp = 20 µs) IFGM = 1 A (tp = 20 µs)
VRGM = 6V
ELECTRICAL CHARACTERISTICS
Symbol
IGT
VGT
IH
Test conditions
VD=12V (DC) RL=33Ω
Symbol
Test conditions
Type
Value
Unit
TN22-1500
VBR
2/7
ID= 5mA
VGK = 0V
Tj = 25°C
MIN
1200
V
MAX
1500
V
TN22
This thyristor has been designed for use as a fluorescent tube starter switch.
■ A pre-heating period during which a heating
An electronic starter circuit provides :
■ One or several high voltage striking pulses
across the lamp.
current is applied to the cathode heaters.
BASIC APPLICATION DIAGRAM
INDUCTANCE
BALLAST
STARTER CIRCUIT
AC
VOLTAGE
FLUORESCENT
TUBE
R
TN22
CONTROLLER
(TIMER)
S
PRINCIPLE OF OPERATION
1/ Pre-heating
At rest the switch S is opened and when the mains
voltage is applied across the circuit a full wave rectified current flows through the resistor R and the
TN22 gate : at every half-cycle when this current
reaches the gate triggering current (IGT) the thyristor turns on.
When the device is turned on the heating current,
limited by the ballast choke, flows through the tube
heaters.
The pre-heating time is typically 2 or 3 seconds.
2/ Pulsing
At the end of the pre-heating phase the switch S is
turned on. At this moment :
If the current through the devices is higher than the
holding current (IH) the thyristor remains on until
the current falls below IH. Then the thyristor turns
off.
If the current is equal or lower than the holding current the thyristor turns off instantaneously.
When the thyristor turns off the current flowing
through the ballast choke generates a high voltage
pulse. This overvoltage is clamped by the thyristor
avalanche characteristic (VBR).
If the lamp is not struck after the first pulse, the system starts a new ignition sequence again.
3/ Steady state
When the lamp is on the running voltage is about
150V and the starter switch is in the off-state.
IMPLEMENTATION
The resistor R must be chosen to ensure a proper
triggering in the worst case (minimum operating
temperature) according to the specified gate triggering current and the peak line voltage.
Switch S : This function can be realized with a gate
sensitive SCR type : P0130AA 1EA3
This component is a low voltage device (< 50V)
and the maximum current sunk through this switch
can reach the level of the thyristor holding current.
The pre-heating period can be determined by the
time constant of a capacitor-resistor circuit
charged by the voltage drop of diodes used in series in the thyristor cathode.
3/7
TN22
Fig.1 : Maximum average power dissipation versus average on-state current (rectified full sine
wave).
Fig.2 : Correlation between maximum average
power dissipation and maximum allowable temperature (Tamb and Tcase) for different thermal
resistances heatsink + contact.
PT(av) (W)
PT(av) (W)
6
6
= 180
5
= 120
4
= 90
= 60
3
= 30
2
Rth=8 o C/W
o
Rth=12 oC/W
o
4
o
3
o
2
= 180
0.2 0.4 0.6 0.8
o
1.2 1.4 1.6 1.8 2
1
Fig.3 : Average on-state current versus case temperature (rectified full sine wave).
Tcase ( C)
0
0
10
20
30
40
50
60
70
80
90 100 110
Fig.4 : Thermal transient impedance junction to
ambient versus pulse duration.
I T(av) (A)
2.0
1.8
o
1.6
= 180
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
0.0 10 20
o
1
I T(av) (A)
0
Rth=0 o C/W
5
o
1
0
Rth=4 o C/W
Zth(j-a)(oC/W)
1.0E+02
1.0E+01
1.0E+00
o
Tcase ( C)
30 40
50 60
70 80
90 100 110
Fig.5 : Relative variation of gate trigger current
and holding current versus junction temperature.
Igt[Tj]
o
Igt[Tj=25 C]
Ih[Tj]
Ih[Tj=25 o C]
1.0E-01
1.0E-02
tp(S)
1.0E-01 1.0E+00 1.0E+01 1.0E+02 1.0E+03
Fig.6 : Non repetitive surge peak on-state current
versus number of cycles.
ITSM(A)
20
3.0
Tj initial = 25oC
F = 50Hz
18
16
2.5
14
2.0
12
Igt
10
1.5
8
Ih
6
1.0
4
0.5
2
Tj(oC)
0.0
-40
4/7
-20
0
20
40
60
80
100
120
140
0
1
Number of cycles
10
100
1000
TN22
Fig.7 : Non repetitive surge peak on-state current
for a sinusoidal pulse with width : tp = 10ms, and
corresponding value of I2t.
Fig.8 : On-state characteristics (maximum values).
I TSM (A). I2 t (A2 s)
VTM (V)
100
o
Tj initial = 25 C
8
7
I TSM
Tj=110 oC
Vto =2.50V
Rt =0.235
6
Tj=110 oC
5
10
4
Tj=25 oC
3
2
I2 t
1
1
10
Fig.9 : Relative variation of holding current versus
gate-cathode resistance (typical values).
500
I TM (A)
tp(ms)
1
0
0.1
10
20
Fig.10 : Maximum allowable RMS current versus
time conduction and initial case temperature.
Note : Calculation made fot Tj max = 135°C (the
failure mode will be short circuit)
IH (mA)
Tj=25 oC
1
11
IT(rms) (A)
10
Tc initial = 25 oC
9
100
8
7
Tc initial = 45 oC
6
5
10
Tc initial = 65 oC
4
3
2
Rgk( )
1
1
10
100
1000
1
0.1
tp(s)
1
10
100
ORDERING INFORMATION
TN
2
2
-
1500
B
(-TR)
STARTLIGHT
DEVICE
IT(RMS) MAX
2: 2 A
VBR max:
1500: 1500V
IGT MAX
2: 1.5 mA
PACKAGE:
B: DPAK
H: IPAK
PACKING MODE:
Blank: Tube
-TR: DPAK Tape & Reel
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TN22
PACKAGE MECHANICAL DATA
DPAK
DIMENSIONS
REF.
Millimeters
Min.
6.7
6.7
3
3
1.6
1.6
2.3
6/7
2.3
Min.
Max.
A
2.2
2.4
0.086
0.094
A1
0.9
1.1
0.035
0.043
A2
0.03
0.23
0.001
0.009
B
0.64
0.9
0.025
0.035
B2
5.2
5.4
0.204
0.212
C
0.45
0.6
0.017
0.023
C2
0.48
0.6
0.018
0.023
D
6.0
6.2
0.236
0.244
E
6.4
6.6
0.251
0.259
G
4.4
4.6
0.173
0.181
H
9.35
10.1
0.368
0.397
L2
FOOTPRINT
Max
Inches
0.80 typ.
0.031 typ.
L4
0.6
1.0
0.023
0.039
V2
0°
8°
0°
8°
TN22
PACKAGE MECHANICAL DATA
IPAK
DIMENSIONS
REF.
A
E
C2
B2
L2
D
H
L
L1
B3
B6
A1
B
V1
B5
C
G
A3
Millimeters
Inches
Min. Typ. Max. Min. Typ. Max.
2.2
2.4 0.086
0.094
0.9
1.1 0.035
0.043
0.7
1.3 0.027
0.051
0.64
0.9 0.025
0.035
5.2
5.4 0.204
0.212
0.85
0.033
0.3
0.035
0.95
0.037
0.45
0.6 0.017
0.023
0.48
0.6 0.019
0.023
6
6.2 0.236
0.244
6.4
6.6 0.252
0.260
4.4
4.6 0.173
0.181
15.9
16.3 0.626
0.641
9
9.4 0.354
0.370
0.8
1.2 0.031
0.047
0.8
1
0.031 0.039
10°
10°
A
A1
A3
B
B2
B3
B5
B6
C
C2
D
E
G
H
L
L1
L2
V1
OTHER INFORMATION
Type
Marking
Package
Weight
Base Qty
Delivery mode
TN22-1500B
TN221500
DPAK
0.3 g
75
Tube
TN22-1500B-TR
TN221500
DPAK
0.3 g
2500
Tape & Reel
TN22-1500H
TN221500
IPAK
0.4 g
75
Tube
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of
use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by
implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to
change without notice. This publication supersedes and replaces all information previously supplied.
STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.
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© 2000 STMicroelectronics - Printed in Italy - All rights reserved.
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