PR26MF12NSZ/
PR36MF12NSZ Series
PR26MF12NSZ/PR36MF12NSZ Series
■ Model Line-up
■ Outline Dimensions (Unit : mm)
For 200V lineFor 100V line
No built-in zero-
cross circuit
Built-in zero-
cross circuit
PR26MF12NSZ
−
PR36MF12NSZ
∗(PR36MF12YSZ)
PR36MF22NSZ
∗(PR36MF22YSZ)
∗ VDE (VDE0884) approved type
■ Absolute Maximum Ratings
*1 The derating factors of absolute maximum ratings due to ambient temperature are
shown in Fig.1, 2, 3, 4
*2 40 to 60%RH, AC for 1 minute, f=60Hz
Parameter Symbol Rating Unit
Forward current IF50
0.6
mA
Reverse voltage
RMS ON-state current
Peak one cycle surge current
Input
PR26MF12NSZ
PR36MF12NSZ
PR36MF22NSZ
Output
VR6V
A
V
Isurge
6 (50Hz sine wave)
600
400 A
VDRM
Viso (rms)
IT (rms)
kV
Isolation voltage
Operating
temperature Topr
−40 to +125
−25 to +85
−30 to +85 °C
°C
Storage temperature Tstg
*2
*1
*1
Soldering temperature Tsol
260 (For 10s)
4.0
°C
(Ta=25°C)
PR26MF12NSZ
PR36MF12NSZ
PR36MF22NSZ
Repetitive
peak OFF-
state voltage
1. Various types of home appliances
■ Features
■ Applications
8-Pin DIP Type SSR for Low
Power Control
1. Compact 8-pin dual-in-line package type
2. RMS ON-state current IT (rms):0.6A
3. Low minimum trigger current (IFT≤5mA)
4. Built-in zero-cross circuit (PR36MF22NSZ)
5. High repetitive peak OFF-state voltage
PR26MF12NSZ VDRM:MIN. 400V
PR36MF12NSZ/PR36MF22NSZ VDRM:MIN. 600V
6. Isolation voltage between input and output
(Viso (rms):4kV)
7. Recognized by UL (No. E94758)
8. Recognized by CSA (No. LR63705)
9. VDE (VDE0884) approved type
(PR36MF12YSZ, PR36MF22YSZ) is
also available as an option
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.
Internet Internet address for Electronic Components Group http://sharp-world.com/ecg/
Terminal , and are common ones of cathode.To radiate the
heat, solder all of the lead pins on the pattern of PWB.
Internal connection Diagram
PR36MF22NSZPR26MF12NSZ/
PR36MF12NSZ
θ
❈
Zero-cross
circuit
Anode
mark
(Model No.)
R26MF1
R36MF1
R36MF2
❈Zero-cross circuit for (PR36MF22NSZ)
θ:0 to 13˚
2.54±0.25
6.5±0.5
1.2±0.3
9.66±0.5
3.5
±0.5
7.62±0.3
2.9±0.5
3.25±0.5
0.5±0.1
0.5TYP.
0.26±0.1
8
AA
6 5
1 2 3 4
1
1 3 4
8 6 5
2 3 41
8 6 5
2 3 4
Cathode
Anode
Cathode
Cathode
G
T1
T2
1
2
3
4
5
6
8
2
Rank
mark
Brand name "S"
PR26MF12NSZ/PR36MF12NSZ Series
Parameter Conditions
Input Forward voltage IF=20mA
IF=10mA, R load
ON-state voltage
Output VD=6V
Critical rate of rise of OFF-state voltage
VD=1/√−
2 • VDRM
Transfer
charac-
teristics
Minimum trigger current VD=6V, RL=100Ω
VD=6V, RL=100Ω, IF=10mA
MIN.
−
−
−
100
5×1010
TYP.
1.2
−
−
1011
MAX.
1.4
3.0
25
−−
−
Holding current
Symbol
VF
VT
VOX
IH
dV/dt
IFT
Isolation resistance RISO
IT=0.6A
Unit
V
Reverse current VR=3V
VD=VDRM
IR
Repetitive peak OFF-state current IDRM
mA
−−10 µA
−−100 µA
V/µs
−−5mA
Ω
V
−−35 V
(Ta=25˚C)
Turn-on time −−
100
50
ton µs
DC=500V, 40 to 60%RH
PR26MF12NSZ/PR36MF12NSZ
PR36MF22NSZ
PR36MF22NSZ
Zero-cross voltage
■ Electrical Characteristics
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
−25−20 −100 102030405060708090100
RMS ON-state current IT (rms) (A)
Ambient temperature Ta (˚C)
0
10
20
30
40
50
60
70
−25−20−100 102030405060708090100
Forward current IF (mA)
Ambient temperature Ta (˚C)
Fig.1
RMS ON-state Current vs. Ambient
Temperature (PR26MF12NSZ/PR36MF12NSZ)
Fig.3
Forward Current vs. Ambient Temperature
(PR26MF12NSZ/PR36MF12NSZ)
−30 −20 −100 102030405060708090100
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
RMS ON-state current IT (rms) (A)
Ambient temperature Ta (˚C)
0
10
20
30
40
50
60
70
−30 −20 −100 102030405060708090100
Forward current IF (mA)
Ambient temperature Ta (˚C)
Fig.2 RMS ON-state Current vs. Ambient
Temperature (PR36MF22NSZ)
Fig.4 Forward Current vs. Ambient
Temperature (PR36MF22NSZ)
PR26MF12NSZ/PR36MF12NSZ Series
1
1.2
1.1
1.4
1.3
1.5
1.6
−40 0−20 20 40 60 80 120100
ON-state voltage VT (V)
Ambient temperature Ta (˚C)
IT=0.6A
10
102
103
−30 0 20406080100
Relative holding current I
H
(t˚C) / I
H
(25˚C)×100%
Ambient temperature Ta (˚C)
VD=6V
Fig.8
ON-state Voltage vs. Ambient Temperature
(PR26MF12NSZ/PR36MF12NSZ)
Fig.10
R
elative Holding Current vs. Ambient
Temprature (PR26MF12NSZ/PR36MF12NSZ)
50
20
5
2
1
100
10
Forward current IF (mA)
Forward voltage VF (V)
−25˚C
25˚C0˚C
Ta=75˚C
50˚C
10.9 1.1 1.2 1.3 1.4 1.5 0
1
2
3
4
6
5
Minimum trigger current IFT (mA)
Ambient temperature Ta (˚C)
VD=6V
RL=100Ω
−30 −10 0−20 20 40 60 80 10010 30 50 70 90
Fig.5 Forward Current vs. Forward Voltage Fig.6
Minimum Trigger Current vs. Ambient
Temperature (PR26MF12NSZ/PR36MF12NSZ)
Fig.9 ON-state Voltage vs. Ambient
Temperature (PR36MF22NSZ)
Fig.7 Minimum Trigger Current vs. Ambient
Temperature (PR36MF22NSZ)
0.8
1
0.9
1.2
1.1
1.3
1.4
−30 0 20406080100
ON-state voltage VT (V)
Ambient temperature Ta (˚C)
IT=0.6A
Minimum trigger current IFT (mA)
Ambient temperature Ta (°C)
−30
0
−20 −10
20 40 60 80 10010 30 50 70 90
0
1
2
3
4
6
5
VD=6V
RL=100Ω
PR26MF12NSZ/PR36MF12NSZ Series
Fig.14 ON-state Current vs. ON-state
Voltage (PR36MF22NSZ)
Fig.11
Relative Holding Current vs. Ambient
Temperature (PR36MF22NSZ)
Fig.12 Zero-cross Voltage vs. Ambient
Temperature (PR36MF22NSZ)
0
0.2
0.4
0.6
0.8
1
1.2
0 0.5 1 1.5
ON-state current IT (A)
ON-state voltage VT (V)
IF=20mA
Ta=25˚C
10
102
103
−30 0 20406080100
Relative holding current I
H
(t˚C) / I
H
(25˚C)×100%
Ambient temperature Ta (˚C)
VD=6V
0
10
5
15
−30
0
−20 −10
20 40 60 80 10010 30 50 70 90
Zero-cross voltage VOX (V)
Ambient temperature Ta (˚C)
R load, IF=10mA
0
0.2
0.4
0.6
0.8
1
1.2
0 0.5 1 1.5 2
ON-state current IT (A)
ON-state voltage VT (V)
IF=20mA
Ta=25˚C
100
10
1
VD=6V
RL=100Ω
Ta=25˚C
Forward current IF (mA)
Turn-on time tON (µs)
100
12030
4050
10
5
Fig.13
ON-state Current vs. ON-state Voltage
(PR26MF12NSZ/PR36MF12NSZ)
Fig.15 Turn-on Time vs. Forward Current
(PR26MF12NSZ/PR36MF12NSZ) Fig.16 Turn-on Time vs. Forward Current
(PR36MF22NSZ)
1 000
100
10
1100
VD=6V
RL=100Ω
Ta=25˚C
12030
4050
10
5
Forward current IF (mA)
Turn-on time tON (µs)
NOTICE
●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.
●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 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).
●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.
●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.
