SHARP S216SE2

S216SE2 Series
∗
IT(rms)≤16A,
Reinforced Insulation Type
Zero Cross type
SIP 4pin
Triac output SSR
■ Description
■ Agency approvals/Compliance
S216SE2 Series reinforced insulation type Solid
State Relays (SSR) are an integration of an infrared
emitting diode (IRED), a Phototriac Detector and a
main output Triac. These devices are ideally suited for
controlling high voltage AC loads with solid state
reliability while providing 3.0kV isolation (V iso(rms) )
from input to output.
1. Approved by TÜV EN60950 (reinforced insulation),
file No. R9051479 (as models No. S216SE2)
2. Package resin : UL flammability grade (94V-0)
S216SE2 Series
Non-zero cross type is also available. (S216SE1 Series)
■ Applications
1. Isolated interface between high voltage AC devices
and lower voltage DC control circuitry.
2. Switching motors, fans, heaters, solenoids, and
valves.
3. Power control in applications such as lighting and
temperature control equipment.
■ Features
1. Output current, IT(rms)≤16.0A
2. Zero crossing functionary (VOX : MAX. 35V)
3. 4 pin SIP package
4. High repetitive peak off-state voltage (VDRM : 600V)
5. Reinforced insulation type (MIN. 0.4mm internal
separation)
6. High isolation voltage between input and output
(Viso(rms) : 3.0kV)
7. Lead-free terminal components are also available
(see Model Line-up section in this datasheet)
8. Screw hole for heat sink
Notice The content of data sheet is subject to change without prior notice.
In the absence of confirmation by device specification sheets, SHARP takes no responsibility for any defects that may occur in equipment using any SHARP
devices shown in catalogs, data books, etc. Contact SHARP in order to obtain the latest device specification sheets before using any SHARP device.
1
Sheet No.:D4-A03501EN
Date Apr. 28. 2004
© SHARP Corporation
S216SE2 Series
■ Internal Connection Diagram
1
2
3
4
1
2
Output (Triac T2)
Output (Triac T1)
Input (+)
Input (−)
3 4
Zero Crossing Circuit
■ Outline Dimensions
5.0±0.3
3.2±0.2
18.5±0.2
16.4±0.3
(Unit : mm)
φ3.2±0.2
Common to pin No.1
Common to pin No.1
5.5±0.2
TÜV mark
S216SE2
Model No.
4-0.8±0.2
1
2
Date code (2 digit)
4.2MAX.
4-1.25±0.3
(5.08)
+−
2MAX.
4-1.1
11.2MIN.
16A260VAC
±0.2
3 4
(7.62)
(36.0)
19.6±0.2
Epoxy resin
(2.54)
0.6±0.1
(1.4)
Product mass : approx. 6.3g
( ) : Typical dimensions
Sheet No.: D4-A03501EN
2
S216SE2 Series
Date code (2 digit)
A.D.
1990
1991
1992
1993
1994
1995
1996
1997
1998
1999
2000
2001
1st digit
Year of production
A.D
Mark
2002
A
2003
B
2004
C
2005
D
2006
E
2007
F
2008
H
2009
J
2010
K
2011
L
2012
M
··
N
·
Mark
P
R
S
T
U
V
W
X
A
B
C
··
·
2nd digit
Month of production
Month
Mark
January
1
February
2
March
3
April
4
May
5
June
6
July
7
August
8
September
9
October
O
November
N
December
D
repeats in a 20 year cycle
Country of origin
Japan
Rank mark
There is no rank mark indicator and currently there are no rank offered for this device.
Sheet No.: D4-A03501EN
3
S216SE2 Series
(Ta=25˚C)
Parameter
Symbol Rating
Unit
*3
Forward current
IF
50
mA
Input
Reverse voltage
VR
6
V
RMS ON-state current
IT (rms)
16 *3
A
*4
Peak one cycle surge current
Isurge
160
A
Repetitive
600
VDRM
V
peak OFF-state voltage
Output
Non-Repetitive
600
VDSM
V
peak OFF-state voltage
Critical rate of rise of ON-state current dIT/dt
50
A/µs
Operating frequency
45 to 65
f
Hz
*1
Isolation voltage
3.0
Viso(rms)
kV
Operating temperature
Topr −25 to +100
˚C
Storage temperature
Tstg −30 to +125
˚C
*2 Soldering temperature
Tsol
260
˚C
1.5mm
■ Absolute Maximum Ratings
Soldering area
*1 40 to 60%RH, AC for 1minute, f=60Hz
*2 For 10s
*3 Refer to Fig.1, Fig.2
*4 f=60Hz sine wave, Tj=25˚C start
■ Electro-optical Characteristics
(Ta=25˚C)
Parameter
Symbol
Conditions
MIN.
−
VF
IF=20mA
Forward voltage
Input
−
IR
VR=3V
Reverse current
−
VD=VDRM
IDRM
Repentitive peak OFF-stage current
I
(rms)=16A,
Resistance
load,
I
=20mA
V
(rms)
−
ON-state voltage
T
F
T
IH
−
−
Output Holding current
VD=2/3•VDRM
dV/dt
30
Critical rate of rise of OFF-state voltage
5
Critical rate of rise of OFF-state voltage at commutaion (dV/dt)c Tj=125˚C, VD=2/3•VDRM, dIT/dt=−8.0A/ms
VD=6V, RL=30Ω
IFT
−
Minimum trigger current
IF=8mA
VOX
−
Transfer Zero cross voltage
DC500V, 40 to 60%RH
RISO
1010
charac- Isolation resistance
teristics Turn-on time
VD(rms)=200V, AC60Hz
ton
−
(rms)=2A,
Resistance
load,
I
=20mA
I
t
Turn-off time
−
T
F
off
Between junction and case
Rth(j-c)
−
Thermal resistance
Between junction and ambient
Rth(j-a)
−
TYP.
1.2
−
−
−
−
−
−
−
−
−
−
−
3.3
40
MAX. Unit
1.4
V
µA
100
µA
100
V
1.5
mA
50
V/µs
−
V/µs
−
mA
8
V
35
Ω
−
ms
9.3
ms
9.3
−
˚C/W
−
Sheet No.: D4-A03501EN
4
S216SE2 Series
■ Model Line-up (1) (Lead-free terminal components)
Shipping Package
EN60950 (reinforced insulation)
Model No.
Case
200pcs/case
−
−
Approved
S216SE2F
VDRM
[V]
IFT[mA]
(VD=6V,
RL=30Ω)
600
MAX.8
■ Model Line-up (2) (Lead solder plating components)
Shipping Package
EN60950 (reinforced insulation)
Model No.
Case
200pcs/case
−
−
Approved
S216SE2
VDRM
[V]
IFT[mA]
(VD=6V,
RL=30Ω)
600
MAX.8
Please contact a local SHARP sales representative to see the actual status of the production.
Sheet No.: D4-A03501EN
5
S216SE2 Series
Fig.1 Forward Current vs.
Ambient Temperature
Fig.2 RMS ON-state Current vs.
Ambient Temperature
60
4
RMS ON-state current IT (rms)(A)
Forward current IF (mA)
50
40
30
20
10
0
−25
0
25
50
75
100
3
2
1
0
−25
125
0
25
Ambient temperature Ta (˚C)
50
75
100
125
Ambient temperature Ta (˚C)
Fig.3 RMS ON-state Current vs.
Case Temperature
Fig.4 Forward Current vs. Forward Voltage
20
100
50˚C
16
Forward current IF (mA)
RMS ON-state current IT (rms)(A)
Ta=75˚C
12
8
25˚C
0˚C
−25˚C
10
4
0
−25
0
25
50
75
100
1
0.9
125
1.0
1.1
Case temperature Tc (˚C)
1.3
1.4
1.5
Forward voltage VF (V)
Fig.5 Surge Current vs. Power-on Cycle
Fig.6 Maximum ON-state Power Dissipation
vs. RMS ON-state Current
20
200
Maximum ON-state power dissipation (W)
f=60Hz
Tj=25˚C Start
180
160
Surge current Isurge (A)
1.2
140
120
100
80
60
40
20
0
Ta=25˚C
18
16
14
12
10
8
6
4
2
0
1
10
0
100
Power-on cycle (Times)
2
4
6
8
10
12
14
16
RMS ON-state current IT (rms)(A)
Sheet No.: D4-A03501EN
6
S216SE2 Series
Fig.7 Minimum Trigger Current vs.
Ambient Temperature
Fig.8 Repetitive Peak OFF-state Current vs.
Ambient Temperature
10−3
12
Repetitive peak OFF-state current IDRM (A)
Minimum trigger current IFT (mA)
VD=6V
RL=30Ω
10
8
6
4
2
0
−25
0
25
50
75
100
10−4
10−5
10−6
10−7
10−8
10−9
−25
125
VD=600V
Ambient temperature Ta (˚C)
0
25
50
75
100
125
Ambient temperature Ta (˚C)
Remarks : Please be aware that all data in the graph are just for reference.
Sheet No.: D4-A03501EN
7
S216SE2 Series
■ Design Considerations
● Recommended Operating Conditions
Input
Parameter
Input signal current at ON state
Input signal current at OFF state
Load supply voltage
Output Load supply current
Frequency
Operating temperature
Symbol
IF(ON)
IF(OFF)
VOUT(rms)
IOUT(rms)
f
Topr
Conditions
−
−
−
Locate snubber circuit between output terminals
(Cs=0.1µF, Rs=47Ω)
−
−
MIN.
16
0
80
0.1
47
−20
MAX.
24
0.1
240
IT(rms)
×80%(∗)
63
80
Unit
mA
mA
V
mA
Hz
˚C
(∗) See Fig.2 about derating curve (IT(rms) vs. ambient temperature).
● Design guide
In order for the SSR to turn off, the triggering current (lF) must be 0.1mA or less.
When the input current (IF) is below 0.1mA, the output Triac will be in the open circuit mode. However, if the
voltage across the Triac, VD, increases faster than rated dV/dt, the Triac may turn on. To avoid this situation,
please incorporate a snubber circuit. Due to the many different types of load that can be driven, we can
merely recommend some circuit vales to start with : Cs=0.1µF and Rs=47Ω. The operation of the SSR and
snubber circuit should be tested and if unintentional switching occurs, please adjust the snubber circuit
component values accordingly.
When making the transition from On to Off state, a snubber circuit should be used ensure that sudden drops
in current are not accompanied by large instantaneous changes in voltage across the Triac.
This fast change in voltage is brought about by the phase difference between current and voltage.
Primarily, this is experienced in driving loads which are inductive such as motors and solenoids.
Following the procedure outlined above should provide sufficient results.
For over voltage protection, a Varistor may be used.
Any snubber or Varistor used for the above mentioned scenarios should be located as close to the main
output triac as possible.
Particular attention needs to be paid when utilizing SSRs that incorporate zero crossing circuitry.
If the phase difference between the voltage and the current at the output pins is large enough, zero crossing
type SSRs cannot be used. The result, if zero crossing SSRs are used under this condition, is that the SSR
may not turn on and off irregardless of the input current. In this case, only a non zero cross type SSR should
be used in combination with the above mentioned snubber circuit selection process.
The load current should be within the bounds of derating curve. (Refer to Fig.2)
Also, please use the optional heat sink when necessary.
In case the optional heat sink is used and the isolation voltage between the device and the optional heat sink
is needed, please locate the insulation sheet between the device and the heat sink.
When the optional heat sink is equipped, please set up the M3 screw-fastening torque at 0.3 to 0.5N•m.
In order to dissipate the heat generated from the inside of device effectively, please follow the below
suggestions.
Sheet No.: D4-A03501EN
8
S216SE2 Series
(a) Make sure there are no warps or bumps on the heat sink, insulation sheet and device surface.
(b) Make sure there are no metal dusts or burrs attached onto the heat sink, insulation sheet and device
surface.
(c) Make sure silicone grease is evenly spread out on the heat sink, insulation sheet and device surface.
Silicone grease to be used is as follows;
1) There is no aged deterioration within the operating temperature ranges.
2) Base oil of grease is hardly separated and is hardly permeated in the device.
3) Even if base oil is separated and permeated in the device, it should not degrade the function of a device.
Recommended grease : G-746 (Shin-Etsu Chemical Co., Ltd.)
: G-747 (Shin-Etsu Chemical Co., Ltd.)
: SC102 (Dow Corning Toray Silicone Co., Ltd.)
In case the optional heat sink is screwed up, please solder after screwed.
In case of the lead frame bending, please keep the following minimum distance and avoid any mechanical
stress between the base of terminals and the molding resin.
4.4mm MIN.
Some of AC electromagnetic counters or solenoids have built-in rectifier such as the diode.
In this case, please use the device carefully since the load current waveform becomes similar with
rectangular waveform and this results may not make a device turn off.
Example how to equip optional heat sink for reinforced isolation
1) Case of isolation sheet whose thickness is 0.4mm or more (Viso : 3kV or more)
0.4mm thickness or more
isolation sheet
Heat sink
SSR
2) Case of the use of double isolation sheet (Viso : each 3kV or more)
Isolation sheet
Heat sink
SSR
Please keep 5mm distance as minimum between naked metal portion of SSR and heat sink, and also
between naked metal portion of SSR and bis/nut/washer.
However, please avoid the natural rubber for isolation sheet.
Sheet No.: D4-A03501EN
9
S216SE2 Series
● Degradation
In general, the emission of the IRED used in SSR will degrade over time.
In the case where long term operation and / or constant extreme temperature fluctuations will be applied to
the devices, please allow for a worst case scenario of 50% degradation over 5years.
Therefore in order to maintain proper operation, a design implementing these SSRs should provide at least
twice the minimum required triggering current from initial operation.
● Standard Circuit
S216SE2
R1
+VCC
3
SSR
D1
4
V1
Load
1
ZS
AC Line
2
Tr1
ZS : Surge absorption circuit (Snubber circuit)
✩ For additional design assistance, please review our corresponding Optoelectronic Application Notes.
Sheet No.: D4-A03501EN
10
S216SE2 Series
■ Manufacturing Guidelines
● Soldering Method
Flow Soldering (No solder bathing)
Flow soldering should be completed below 260˚C and within 10s.
Preheating is within the bounds of 100 to 150˚C and 30 to 80s.
Please solder within one time.
Other notices
Please test the soldering method in actual condition and make sure the soldering works fine, since the impact
on the junction between the device and PCB varies depending on the tooling and soldering conditions.
Sheet No.: D4-A03501EN
11
S216SE2 Series
● Cleaning instructions
Solvent cleaning :
Solvent temperature should be 45˚C or below. Immersion time should be 3minutes or less.
Ultrasonic cleaning :
The impact on the device varies depending on the size of the cleaning bath, ultrasonic output, cleaning time,
size of PCB and mounting method of the device.
Therefore, please make sure the device withstands the ultrasonic cleaning in actual conditions in advance of
mass production.
Recommended solvent materials :
Ethyl alcohol, Methyl alcohol and Isopropyl alcohol.
In case the other type of solvent materials are intended to be used, please make sure they work fine in actual using conditions since some materials may erode the packaging resin.
● Presence of ODC
This product shall not contain the following materials.
And they are not used in the production process for this device.
Regulation substances : CFCs, Halon, Carbon tetrachloride, 1.1.1-Trichloroethane (Methylchloroform)
Specific brominated flame retardants such as the PBBOs and PBBs are not used in this product at all.
Sheet No.: D4-A03501EN
12
S216SE2 Series
■ Package specification
Package materials
Packing case : Corrugated cardboard
Partition : Corrugated cardboard
Pad : Corrugated cardboard
Cushioning material : Polyethylene
Molt plane : Urethane
Package method
The product should be located after the packing case is partitioned and protected inside by 4 pads.
Each partition should have 5 products with the lead upward.
Cushioning material and molt plane should be located after all products are settled (1 packing contains 200
pcs).
Package composition
Molt plane
Cushioning material
Product
Pad
Partition
Packing case
Sheet No.: D4-A03501EN
13
S216SE2 Series
■ Important Notices
with equipment that requires higher reliability such as:
--- Transportation control and safety equipment (i.e.,
aircraft, trains, automobiles, etc.)
--- Traffic signals
--- Gas leakage sensor breakers
--- Alarm equipment
--- Various safety devices, etc.
(iii) SHARP devices shall not be used for or in connection with equipment that requires an extremely high level of reliability and safety such as:
--- Space applications
--- Telecommunication equipment [trunk lines]
--- Nuclear power control equipment
--- Medical and other life support equipment (e.g.,
scuba).
· The circuit application examples in this publication are
provided to explain representative applications of
SHARP devices and are not intended to guarantee any
circuit design or license any intellectual property rights.
SHARP takes no responsibility for any problems related to any intellectual property right of a third party resulting from the use of SHARP's devices.
· Contact SHARP in order to obtain the latest device
specification sheets before using any SHARP device.
SHARP reserves the right to make changes in the specifications, characteristics, data, materials, structure,
and other contents described herein at any time without
notice in order to improve design or reliability. Manufacturing locations are also subject to change without notice.
· If the SHARP devices listed in this publication fall within the scope of strategic products described in the Foreign Exchange and Foreign Trade Law of Japan, it is
necessary to obtain approval to export such SHARP devices.
· Observe the following points when using any devices
in this publication. SHARP takes no responsibility for
damage caused by improper use of the devices which
does not meet the conditions and absolute maximum
ratings to be used specified in the relevant specification
sheet nor meet the following conditions:
(i) The devices in this publication are designed for use
in general electronic equipment designs such as:
--- Personal computers
--- Office automation equipment
--- Telecommunication equipment [terminal]
--- Test and measurement equipment
--- Industrial control
--- Audio visual equipment
--- Consumer electronics
(ii) Measures such as fail-safe function and redundant
design should be taken to ensure reliability and safety
when SHARP devices are used for or in connection
· This publication is the proprietary product of SHARP
and is copyrighted, with all rights reserved. Under the
copyright laws, no part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, for any purpose, in whole or in
part, without the express written permission of SHARP.
Express written permission is also required before any
use of this publication may be made by a third party.
· Contact and consult with a SHARP representative if
there are any questions about the contents of this publication.
Sheet No.: D4-A03501EN
14