|
Sharp Electrionic Components |
S101S15V/S101S16V
S201S15V/S201S16V
S101S15V/S101S16V/S201S15V/S201S16V
SIP Type SSR with Built-in
Snubber Circuit
s Features
1. High radiation resin mold package
IT : MAX. 3A rms
2. Isolation voltage between input and output
Viso : 3 000 Vrms
3. Built-in zero-cross circuit
(S101S16V/ S201S16V)
4. Built-in snubber circuit
5. Recognized by UL, file No. E94758
Approved by CSA, file No. LR63705
s Applications
1. Air conditioners
2. OA equipment
s Model Line-ups
No built-in
zero-cross circuit
Built-in zero-cross
circuit
For 100V lines
S101S15V
S101S16V
For 200V lines
S201S15V
S201S16V
s Absolute Maximum Ratings (Ta = 25˚C )
Parameter
Forward current
Input
Reverse current
Output
RMS ON-state current
*1 Peak one cycle surge
current
Repetitive peak OFF-
state voltage
Critical rate of rise of
ON-state current
Operating frequency
Operating temperature
Storage temperature
*2 Isolation voltage
*3 Soldering temperature
Ratings
Symbol
Unit
100V line 200V line
IF 50 mA
VR 6
V
IT 3 ( Tc<=100˚C) A rms
I surge
30
A
V DRM 400 600 V
dIT /dt 40 A/µ s
f 45 to 65 H Z
T opr - 20 to + 80 ˚C
T stg - 30 to + 100 ˚C
V iso
3.0 kV rms
T sol 260
˚C
s Outline Dimensions
(Unit : mm )
Common to Pin No.1
A Model No, B
S101S15V 3A125VAC
S101S16V
S201S15V
S201S16V
3A265VAC
g
4 - 1.1 ± 0.2
4 - 1.25 ± 0.3
4 - 0.8 ± 0.2
18.5 ± 0.2
16.4 ± 0.3
φ 3.2 ± 0.2
Common to Pin No.1
5.5 ± 0.2
A
B
+-
1 23 4
(5.08) (7.62)
Internal connection diagram
S101S15V/S201S15V
(2.54)
0.6± 0.1 (1.4)
g May not be externally
connected
S101S16V/S201S16V
Zero-cross
circuit
1 2 34
1 Output (Triac T2 )
2 Output (Triac T1 )
3 Input ( + )
4 Input ( - )
1 2 34
1 Output (Triac T2 )
2 Output (Triac T1 )
3 Input ( + )
4 Input ( - )
*1 60H Z sine wave, Tj = 25˚C
*2 AC 60Hz for 1 minute, 40 to 60% RH
Isolation voltage measuring method:
( 1) Dielectric withstand tester, with zero-cross circuit shall be used.
( 2) The waveform of applied voltage shall be sine wave.
( 3) It shall be applied voltage between input and output.
( Input and output shall be short-circuited respectively)
*3 For 10 seconds
“ In the absence of confirmation by device specification sheets, SHARP takes no responsibility for any defects that occur in equipment using any of SHARP's devices, shown in catalogs,
data books, etc. Contact SHARP in order to obtain the latest version of the device specification sheets before using any SHARP's device.”
S101S15V/S101S16V/S201S15V/S201S16V
s Electrical Characteristics
Input
Output
Parameter
Forward voltage
Reverse current
Symbol
VF
IR
ON-state voltage
VT
Minimum oper-
ating current
S101S15V/16V
S201S15V/16V
I OP
Open circuit
leak current
S101S15V/16V
S201S15V/16V I leak
Critical rate of rise of OFF-state voltage
dV/dt
Commutation critical rate of rise
of OFF-state voltage
(dV/dt)c
Minimum trig-
ger current
S101S15V/S201S15V
S101S16V/S201S16V
I FT
Condition
IF = 20mA
VR = 3V
Resistance load, I F = 20mA,
IT = 1.5A rms
V OUT = 120V rms
V OUT = 240V rms
V OUT = 120V rms
V OUT = 240V rms
V D = 2/3V DRM
T j = 125˚C, VD= 400V,
dI T/d t = -1.5A/ms
VD = 12V, R L = 30 Ω
VD = 6V, R L = 30 Ω
Isolation resistance
R ISO DC500V, R H = 40 to 60%
Transfer
charact-
eristics
Zero-cross
voltage
S101S16V
S201S16V
Turn-on time
S101S15V/S201S15V
S101S16V/S201S16V
Turn-off time
Thermal resistance Between junction and case
Thermal resistance Between junction and ambient
V OX
ton
toff
R th (j-c)
R th (j-a)
IF = 15mA
AC50H Z
AC50H Z
-
-
MIN.
-
-
-
TYP.
1.2
-
-
(Ta = 25˚C )
MAX.
1.4
10-4
Unit
V
A
1.5 V rms
- - 50 mA rms
- -5
- - 10 mA rms
30 -
- V/µ s
4 - - V/µ s
- - 15 mA
1010 -
--
--
--
--
--
-6
- 45
-Ω
35
V
35
1
ms
10
10 ms
- ˚C/W
- ˚C/W
Fig. 1 RMS ON-state Current vs.
Ambient Temperature
(1 ) With heat sink ( Al 100 x 100 x t 2mm)
(2 ) With heat sink ( Al 50 x 50 x t 2mm)
5 Note ) With the Al heat sink set up vertically,
Al plate
install it as shown in the figure
Torque : 4kg•cm
4
Apply thermal conductive silicone grease
on the heat sink mounting plate.forcibly
SSR
cooling shall not be carried out.
3
(2) (1)
2
Without
heat sink
1
0
- 20 0
25 50 75 80 100
Ambient temperature T a (˚C)
125
Fig. 2 RMS ON-state Current vs.
Case Temperature
5
4
3
2
1
0
- 20 60
70 80 90 100 110 120 125 130
Case temperature T c (˚C)
|