TECCOR K1100S

DO-15X
Axial Lead
DO-214AA
Surface Mount
TO-202AB
Type 1
TO-92
Type 70
Do not use mounting tab
or center lead,
electrically connected
SIDAC
(95 - 330 Volts)
9
General Description
The Sidac is a silicon bilateral voltage triggered switch with
greater power-handling capabilities than standard diacs. Upon
application of a voltage exceeding the Sidac breakover voltage
point, the Sidac switches on through a negative resistance region
to a low on-state voltage. Conduction will continue until the current is interrupted or drops below the minimum holding current of
the device.
Applications
•
•
•
•
•
•
•
•
•
Teccor offers the complete voltage range (95-330) over three different packages:
•
TO-92 (95-280 volts)
•
Axial lead DO-15X (95-280 volts)
•
Surface Mount DO-214AA (95-280 volts)
•
TO-202AB (190-330 volts)
Teccor’s Sidacs feature glass passivated junctions to ensure a
rugged and dependable device capable of withstanding harsh
environments.
Features
•
•
•
Variations of devices covered in this data sheet are available for
custom design applications. Please consult the factory for more
information.
Teccor Electronics
(972) 580-7777
High voltage lamp ignitors
Natural gas ignitors
Gas oil ignitors
High voltage power supplies
Xenon ignitors
Over voltage protector
Pulse generators
Fluorescent lighting ignitors
HID lighting ignitors
9-1
AC circuit oriented
Glass-passivated junctions
High surge current capability
SIDAC
Electrical Specifications
IT(RMS)
Part No.
VDRM
On-State
Repetitive
RMS Current
Peak
TJ≤125°C
Off-State
50/60Hz
Voltage
Sine Wave
(7) (8)
Type
DO-15X
TO-92
TO-202AB
DO-214AA
G Package
E Package
F Package
S Package
See “Package Dimensions” section for variations.
Amps
MAX
Volts
MIN
VBO
IDRM
Breakover Voltage
50/60Hz Sine Wave
(1)
Repetitive Breakover
Current
Peak
50/60Hz
Off-State
Current Sine Wave
50/60Hz
Sine Wave
V=VDRM
MIN
MAX
µAmps
MAX
µAmps
MAX
Volts
K1050E70
K1050G
K1050S
1.0
±90
95
113
5
10
K1100E70
K1100G
K1100S
1.0
±90
104
118
5
10
K1200E70
K1300E70
K1200G
K1300G
K1200S
K1300S
1.0
1.0
±90
±90
110
120
125
138
5
5
10
10
K1400E70
K1400G
K1400S
1.0
±90
130
146
5
10
K1500E70
K1500G
K1500S
1.0
±90
140
170
5
10
K2000E70
K2200E70
K2000G
K2200G
K2000F1
K2200F1
K2000S
K2200S
1.0
1.0
±180
±180
190
205
215
230
5
5
10
10
K2400E70
K2400G
K2400F1
K2400S
K2401F1
K2500E70
K2500G
K2500F1
K3000F1
1.0
±190
220
250
5
10
1.0 (10)
±190
220
250
5
10
1.0
1.0
±190
±190
240
270
280
330
5
5
10
10
K2500S
General Notes
Electrical Specification Notes
•
(1)
(2)
(3)
(4)
(5)
(6)
(7)
All measurements are made at 60Hz with a resistive load at an
ambient temperature of +25°C unless otherwise specified.
•
Storage temperature range (TS) is -65°C to +150°C.
•
The case (TC) or lead (TL) temperature is measured as shown on
the dimensional outline drawings. See “Package Dimensions” section of this catalog.
•
Junction temperature range (TJ) is -40°C to +125°C.
•
Lead solder temperature is a maximum of +230°C for 10 seconds
maximum; ≥ 1/16" (1.59mm) from case.
SIDAC
IBO
See Figure 9.6 for VBO change vs junction temperature.
See Figure 9.7 for IBO vs junction temperature.
See Figure 9.2 for IH vs case temperature.
See Figure 9.14 for test circuit.
See Figure 9.1 for more than one full cycle rating.
RθJA for TO-202 Type 23 and Type 41 is 70°C/watt.
TC ≤ 90°C for TO-92 Sidac and TC ≤ 105°C for TO-202 Sidacs.
TL ≤ 100°C for DO-15X and TL ≤ 90°C for DO-214AA.
(8) See Figure 9.15 for clarification of Sidac operation.
(9) For best Sidac operation, the load impedance should be near or
less than switching resistance.
(10) Teccor's new, improved series of sidacs is designed to ensure
goodcommutationathigherswitchingfrequencies asrequiredinignitor
circuits for high intensity discharge (HID) lighting. A typical circuit
for a metal halide lamp ignitor is shown in the schematic, Figure
9.3. With proper component selection this circuit will produce three
pulses for ignition of Osram lamp types such as HQI-T70W, HQIT150W, and HQI-T250W which require a minimum of three pulses
at 4kV magnitude and >1µs duration each at a minimum repetition
rate of 3.3kHz.
9-2
Teccor Electronics
(972) 580-7777
SIDAC
IH
VTM
ITSM
RS
Dynamic
Holding Current
50/60Hz
Sine Wave
R = 100Ω
(3) (4)
Peak
On-State
Voltage
IT = 1 Amp
Peak One
Cycle Surge
Current
50/60Hz Sine Wave
(Non-Repetitive)
(5)
Switching
Resistance
(V
–V )
BO
S
= -------------------------------(I – I
)
S BO
di/dt
Critical
Critical
Rate-of-Rise Rate-of-Rise
of Turn-off
of Off-State
Voltage at
Voltage at
8kHz
Rated VDRM
TJ ≤ 100°C
Critical
Rate-of-Rise
of On-State
Current
Amps
kΩ
Volts/µSec
Volts/µSec
Amps/µSec
MIN
MIN
MIN
TYP
16.7
0.1
20
1500
150
20
20
16.7
16.7
0.1
0.1
20
20
1500
1500
150
150
1.5
20
16.7
0.1
20
1500
150
1.5
20
16.7
0.1
20
1500
150
3.0
1.5
1.5
20
20
16.7
16.7
0.1
0.1
20
20
1500
1500
150
150
1.5
3.0
1.5
20
16.7
0.1
20
1500
150
1.5
3.0
1.5
20
16.7
0.1
20
1500
150
1.5
3.0
3.0
1.5
20
20
16.7
16.7
2.0
0.1
42
20
1500
1500
150
150
20
16.7
0.1
20
1500
150
F
60Hz
TYP
MAX
E
G
60
150
1.5
1.5
1.5
20
60
60
150
150
1.5
1.5
1.5
1.5
1.5
1.5
60
150
1.5
1.5
60
150
1.5
1.5
60
60
150
150
1.5
1.5
1.5
1.5
60
150
1.5
60
150
1.5
60
60
150
150
60
150
1.5
S
dv/dt
50/60Hz Sine Wave
(9)
Volts
Max
Package
mAmps
R
dVq/dt
3.0
50Hz
S
Peak Surge (Non-Repetitive)
On-State Current [I(TSM)] - Amps
100
SUPPLY FREQUENCY: 60 Hz Sinusoidal
LOAD: Resistive
RMS ON-STATE CURRENT: IT RMS Maximum Rated
Value at Specified Junction Temperature
40
20
10
8.0
6.0
BLOCKING CAPABILITY MAY BE LOST
DURING AND IMMEDIATELY
FOLLOWING SURGE CURRENT
INTERVAL
OVERLOAD MAY NOT BE REPEATED
UNTIL JUNCTION TEMPERATURE
HAS RETURNED TO STEADY-STATE
RATED VALUE.
4.0
2.0
1.0
1.0
10
100
1000
Surge Current Duration - Full Cycles
Figure 9.1
V-I Characteristics
Peak Surge Current vs Surge Current Duration
THERMAL RESISTANCE (STEADY STATE)
RθJC [RθJA] °C/W (TYPICAL)
E
G
F (6)
S
35 [95]
18 [75]
7 [45]
30 [85]
Teccor Electronics
(972) 580-7777
9-3
SIDAC
Maximum Allowable Ambient Temperature (TA) - ˚C
Electrical Specifications
1.5
Ratio of
˚
IH
IH(TC=25 C)
2.0
1.0
.5
0
-40
-15
+25
+65
+105
+125
140
CURRENT WAVEFORM: Sinusoidal - 60 Hz
LOAD: Resistive or Inductive
FREE AIR RATING
120
100
80
60
TO
TO
-9
2
02
d
40
TO
-2
an
-2
02
TY
PE
DO
-2
23
14
TY
PE
&
1
41
25
20
˚
Case Temperature (TC) - C
0
0.2
0.4
0.6
0.8
1.0
RMS On-State Current [IT(RMS)] - Amps
Figure 9.2
Normalized DC Holding Current vs Case/Lead Temperature
Figure 9.5
Maximum Allowable Ambient Temperature vs On-State
Current
Percentage of VBO Change - %
+4
H.V.
STEP-UP
TRANSFORMER
BALLAST
K2401F1
0.1 - 0.15 µF
220V/240V
50/60Hz
METAL
HALIDE
LAMP
5 - 6µH
5.6K - 8.2K
5W
0.22 - 0.33 µF
+2
0
-2
-4
-6
-8
-10
-12
+25
-40
-20
Typical Metal Halide Ignitor Circuit
Typical Metal Halide Ignitor Circuit
+60
+80
+100
+120 +140
Normalized V BO Change vs Junction Temperature
Figure 9.6
ITRM
VBO Firing
Current
Waveform
No
n-R
ep
200
Re
ea
ted
pe
titi
100
80
60
40
on
f=1
f=5
to
l/f
eq
ue
nc
z
00
f=1
Fr
0H
f=1
20
yf
=5
Hz
Hz
TJ=125ºC Max
kH
z
kH
z
f=1
0k
2
+40
di/dt Limit Line
600
400
10
8
6
4
+20
Junction Temperature (TJ) - ˚C
Repetitive Peak Breakover
Current (IBO) Multiplier
Repetitive Peak On-State Current (ITRM) - Amps
Figure 9.3
0
f=20
1
0.8
0.6
2 x 10-3
4
Hz
9
8
7
6
5
4
V=VBO
3
2
1
20
30
40
50
60
70
80
90
100
110 120 130
Junction Temperature (TJ) - C
˚
kHz
6 8
1 x 10-2
2
4
6 8
1 x 10-1
2
4 6 81
Pulse base width (to) - mSec.
Figure 9.4
SIDAC
Repetitive Peak On-State Current (I TRM) vs Pulse Width at
Various Frequencies
Figure 9.7
9-4
Normalized Repetitive Peak Breakover Current vs Junction
Temperature
Teccor Electronics
(972) 580-7777
SIDAC
9
TL =25˚C
Positive or Negative Instantaneous
On-State Current (iT) - Amps
8
4.7 µF
TO-92, DO-214AA & DO-15X
"E", "S" and "G" Packages
7
-
10 µF
-
6
+
100V
4.7 kΩ
+
50V
K1200E
SIDAC
½W
+
-
5
4
4.7 µF
100V
1.2 µF
200V
24 VAC
60 Hz
3
TO-202 "F" Package
2
1
0
0
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2 2.4
2.6
2.8
3.0
3.2
3.4
H.V.
IGNITOR
3.6
Positive or Negative Instantaneous On-State Voltage (vT) - Volts
Figure 9.8
On-State Current vs On-State Voltage (Typical)
Ignitor Circuit (Low Voltage Input)
CURRENT WAVEFORM: Sinusoidal
LOAD: Resistive or Inductive
CONDUCTION ANGLE: See Figure 9.15
2.2
2.0
Average On-State Power Dissipation
[PD(AV)] - Watts
Figure 9.11
BALLAST
BALLAST
1.8
1.6
TO-202 "F" Package
0.47µF
400V
SIDAC
1.4
3.3 KΩ
1.2
SIDAC
LAMP
0.22µF
7.5 KΩ
LAMP
1.0
0.8
120 VAC
60 Hz
0.6
220 VAC
60 Hz
16 mH
"E", "S" & "G" Packages
TO-92, DO-214AA & DO-15X
0.4
0.2
0
0.2
0.4
0.6
0.8
120 VAC
1.0
220 VAC
RMS On-State Current [IT(RMS)] - Amps
Figure 9.9
Power Dissipation (Typical) vs On-State Current
Figure 9.12 Typical High Pressure Sodium Lamp Firing Circuit
100Ω
SCR
SIDAC
2w
100-250
VAC
60 Hz
-
10 µF
XENON LAMP
+
250V
20 MΩ
+ 10 µF
- 450V
100-250
VAC
60 Hz
120VAC
60Hz
K2200F1
4KV
SIDAC
.01µF
400V
200400V
TRIGGER
TRANSFORMER
20:1
Figure 9.10 Comparison of Sidac vs SCR
Teccor Electronics
(972) 580-7777
Figure 9.13 Xenon Lamp Flashing Circuit
9-5
SIDAC
Electrical Specifications
PUSH
TO
TEST
S1
100-250
VAC
60 Hz
VBO
SWITCH TO TEST IN
EACH DIRECTION
100 Ω
1%
VBO
IPK
DEVICE
UNDER
TEST
VBO
100-250
VAC
60 Hz
TRACE STOPS
I
H
LOAD
IH
IH
IH
S1
120-145
CONDUCTION
ANGLE
˚
SCOPE INDICATIONS
SCOPE
Figure 9.14 Dynamic Holding Current Test Circuit for Sidacs
LOAD CURRENT
Figure 9.15 Basic Sidac Circuit
(a) Circuit
(b) Waveforms
VBO
R
SIDAC
VDC(IN) ≥ VB0
VC
VC
IL
C
Rmax ≤
Rmin ≥
t
RL
IL
VIN - VBO
I
BO
t
V
-V
IN
TM
IH
(MIN)
Figure 9.16 Relaxation oscillator Using a Sidac
INPUT
VOLTAGE
VCE MONITOR
0V
tw ≈ 3 ms
(See Note A)
(See Note B)
2N6127
(or equivalent)
INPUT
RBB1 =
150Ω
100 mH
TIP-47
5V
COLLECTOR
CURRENT
0.63 A
tw
100 mS
0
50Ω
RBB2 =
100Ω
50Ω
+ VBB2 =0
VBB1 =10 V
+
VCC = 20 V
-
RS = 0.1 Ω
IC MONITOR
SIDAC VBO
COLLECTOR
VOLTAGE
10 V
VCE(sat)
TEST CIRCUIT
VOLTAGE AND CURRENT WAVEFORMS
NOTE A: Input pulse width is increased until ICM = 0.63A.
NOTE B: Sidac (or Diac or series of Diacs) chosen so that VBO is just below VCEO rating of transistor to be protected.
The Sidac (or Diac) eliminates a reverse breakdown of the transistor in inductive switching circuits where otherwise the
transistor could be destroyed.
Figure 9.17 Sidac Added to Protect Transistor for Typical Transistor Inductive Load Switching Requirements
SIDAC
9-6
Teccor Electronics
(972) 580-7777