© Panasonic Corporation 2018
1
industrial.panasonic.com/ac/e/ ASCTB106E 201903
2019.03
ORDERING INFORMATION
TYPICAL APPLICATIONS
FEATURES
RS RELAYS (ARS)
3 GHz capable, 10 W
carrying power (at 3 GHz),
50Ω/75Ω impedance and
1 Form C relays
1. Miniature design
14×8.6×7.2 mm .551×.339×.283
inch (standard PC board terminal)
2. Lineup includes quiet type.
(75Ω type only)
Operation noise (Unit: dB)
3. Excellent high frequency
characteristics
4. Lineup includes surface-mount
terminal type
E and Y layouts available.
If you consider using applications with
low level loads or with high frequency
switching, please consult us.
Protective construction: Sealed type
14.0
.551
8.6
.339 14.0
.551
8.6
.339
7.2
.283 8.0
.315
mm inch
60% OFF in volume
(Compared to
previous our product)
5. Lineup includes reversed contact
type
Great design freedom is possible using
reversed contact type in which the
positions of the N.O. and N.C. contacts
are switched.
1. Broadcasting and video equipment
markets
• Broadcasting equipment
• STB/tuner, etc.
2. Mobile phone base stations
3. Communications market
• Antenna switching
All types of wireless devices
4. Measurement equipment market
• Spectrum analyzer and oscilloscope,
etc.
RS relays
Contact arrangement
1: Standard contact type (1 Form C)
3: Reversed contact type (1 Form C)
Nil:
A:
Y:
ARS
Operating function
0: Single side stable standard type (Impedance: 75Ω)
1: 1 coil latching type (Impedance: 75Ω)
2: 2 coil latching type (Impedance: 75Ω)
3: Single side stable quiet type (Impedance: 75Ω)
4: Single side stable type (Impedance: 50Ω)
5: 1 coil latching type (Impedance: 50Ω)
6: 2 coil latching type (Impedance: 50Ω)
Coil voltage, DC
03: 3 V, 4H: 4.5 V, 09: 9 V, 12: 12 V, 24: 24 V (H=0.5)
Packing style
Nil:
X:
Z:
Carton packing (Standard PC board terminal only)
Tube packing (Surface-mount terminal only)
Tape and reel packing (picked from 2-pin side) (Surface-mount terminal only)
Tape and reel packing (picked from 18-pin side) (Surface-mount terminal only)
Standard PC board terminal
Surface-mount terminal, E layout
Surface-mount terminal, Y layout
RERS
(Quiet type)
30 40
Automation Controls Catalog
RS (ARS)
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© Panasonic Corporation 2019 ASCTB106E 201903
TYPES
3. Surface-mount terminal and standard contact type, E layout
1.Standard PC board terminal and standard contact type
2.Standard PC board terminal and reversed contact type
Note: The box at the end of a part number shows where packing type is indicated. If there is no indication, tube packing will be used.
If “X” or “Z” is added, tape and reel packing will be used. Example: ARS14A03 (tube packing), ARS14A03X (tape and reel packing)
4. Surface-mount terminal and standard contact type, Y layout
Note: The box at the end of a part number shows where packing type is indicated. If there is no indication, tube packing will be used.
If “X” or “Z” is added, tape and reel packing will be used. Example: ARS14Y03 (tube packing), ARS14Y03X (tape and reel packing)
Impedance Rated voltage Part No. Standard packing
Single side stable type 1 coil latching type 2 coil latching type Carton Case
50 Ω
3 V DC ARS1403 ARS1503 ARS1603
50 pcs. 500 pcs.
4.5 V DC ARS144H ARS154H ARS164H
9 V DC ARS1409 ARS1509 ARS1609
12 V DC ARS1412 ARS1512 ARS1612
V DC ARS1424 ARS1524 ARS1624
Impedance Rated voltage
Part No. Standard packing
Standard type Quiet type
Single side stable
type 1 coil latching type 2 coil latching type Single side stable
type Carton Case
75 Ω
3 V DC ARS1003 ARS1103 ARS1203 ARS1303
50 pcs. 500 pcs.
4.5 V DC ARS104H ARS114H ARS124H ARS134H
9 V DC ARS1009 ARS1109 ARS1209 ARS1309
12 V DC ARS1012 ARS1112 ARS1212 ARS1312
24 V DC ARS1024 ARS1124 ARS1224 ARS1324
Impedance Rated voltage Part No. Standard packing
Single side stable type 1 coil latching type 2 coil latching type Carton Case
50 Ω
3 V DC ARS3403 ARS3503 ARS3603
50 pcs. 500 pcs.
4.5 V DC ARS344H ARS354H ARS364H
9 V DC ARS3409 ARS3509 ARS3609
12 V DC ARS3412 ARS3512 ARS3612
24 V DC ARS3424 ARS3524 ARS3624
Impedance Rated voltage
Part No. Standard packing
Standard type Quiet type
Single side stable
type 1 coil latching type 2 coil latching type Single side stable
type Carton Case
75 Ω
3 V DC ARS3003 ARS3103 ARS3203 ARS3303
50 pcs. 500 pcs.
4.5 V DC ARS304H ARS314H ARS324H ARS334H
9 V DC ARS3009 ARS3109 ARS3209 ARS3309
12 V DC ARS3012 ARS3112 ARS3212 ARS3312
24 V DC ARS3024 ARS3124 ARS3224 ARS3324
Impedance Rated voltage
Part No. Standard packing
Single side stable type 1 coil latching type 2 coil latching type Tube Tape and reel Case
50 Ω
3 V DC ARS14A03□ ARS15A03□ ARS16A03□
40 pcs. 500 pcs. 1,000 pcs.
4.5 V DC ARS14A4H□ ARS15A4H□ ARS16A4H□
9 V DC ARS14A09□ ARS15A09□ ARS16A09□
12 V DC ARS14A12□ ARS15A12□ ARS16A12□
24 V DC ARS14A24□ ARS15A24□ ARS16A24□
75 Ω
3 V DC ARS10A03□ ARS11A03□ ARS12A03□
4.5 V DC ARS10A4H□ ARS11A4H□ ARS12A4H□
9 V DC ARS10A09□ ARS11A09□ ARS12A09□
12 V DC ARS10A12□ ARS11A12□ ARS12A12□
24 V DC ARS10A24□ ARS11A24□ ARS12A24□
Impedance Rated voltage
Part No. Standard packing
Single side stable type 1 coil latching type 2 coil latching type Tube Tape and reel Case
50 Ω
3 V DC ARS14Y03□ ARS15Y03□ ARS16Y03□
40 pcs. 500 pcs. 1,000 pcs.
4.5 V DC ARS14Y4H□ ARS15Y4H□ ARS16Y4H□
9 V DC ARS14Y09□ ARS15Y09□ ARS16Y09□
12 V DC ARS14Y12□ ARS15Y12□ ARS16Y12□
24 V DC ARS14Y24□ ARS15Y24□ ARS16Y24□
75 Ω
3 V DC ARS10Y03□ ARS11Y03□ ARS12Y03□
4.5 V DC ARS10Y4H□ ARS11Y4H□ ARS12Y4H□
9 V DC ARS10Y09□ ARS11Y09□ ARS12Y09□
12 V DC ARS10Y12□ ARS11Y12□ ARS12Y12□
24 V DC ARS10Y24□ ARS11Y24□ ARS12Y24□
RS (ARS)
3
Panasonic Corporation Electromechanical Control Business Division
industrial.panasonic.com/ac/e/ © Panasonic Corporation 2019 ASCTB106E 201903
RATING
1.Coil data
1) Single side stable type
• Operating characteristics such as ‘Operate voltage’ and ‘Release voltage’ are inuenced by mounting conditions, ambient temperature, etc.
Therefore, please use the relay within ± 5% of rated coil voltage.
• ‘Initial’ means the condition of products at the time of delivery.
2) 1 coil latching type
Note: The box at the end of a part number shows where packing type is indicated. If there is no indication, tube packing will be used.
If “X” or “Z” is added, tape and reel packing will be used. Example: ARS34A03 (tube packing), ARS34A03X (tape and reel packing)
5. Surface-mount terminal and reversed contact type, E layout
3) 2 coil latching type
Impedance Rated voltage
Part No. Standard packing
Single side stable
type 1 coil latching type 2 coil latching type Tube Tape and reel Case
50 Ω
3 V DC ARS34A03□ ARS35A03□ ARS36A03□
40 pcs. 500 pcs. 1,000 pcs.
4.5 V DC ARS34A4H□ ARS35A4H□ ARS36A4H□
9 V DC ARS34A09□ ARS35A09□ ARS36A09□
12 V DC ARS34A12□ ARS35A12□ ARS36A12□
24 V DC ARS34A24□ ARS35A24□ ARS36A24□
75 Ω
3 V DC ARS30A03□ ARS31A03□ ARS32A03□
4.5 V DC ARS30A4H□ ARS31A4H□ ARS32A4H□
9 V DC ARS30A09□ ARS31A09□ ARS32A09□
12 V DC ARS30A12□ ARS31A12□ ARS32A12□
24 V DC ARS30A24□ ARS31A24□ ARS32A24□
Note: The box at the end of a part number shows where packing type is indicated. If there is no indication, tube packing will be used.
If “X” or “Z” is added, tape and reel packing will be used. Example: ARS34Y03 (tube packing), ARS34Y03X (tape and reel packing)
6. Surface-mount terminal and reversed contact type, Y layout
Impedance Rated voltage
Part No. Standard packing
Single side stable
type 1 coil latching type 2 coil latching type Tube Tape and reel Case
50 Ω
3 V DC ARS34Y03□ ARS35Y03□ ARS36Y03□
40 pcs. 500 pcs. 1,000 pcs.
4.5 V DC ARS34Y4H□ ARS35Y4H□ ARS36Y4H□
9 V DC ARS34Y09□ ARS35Y09□ ARS36Y09□
12 V DC ARS34Y12□ ARS35Y12□ ARS36Y12□
24 V DC ARS34Y24□ ARS35Y24□ ARS36Y24□
75 Ω
3 V DC ARS30Y03□ ARS31Y03□ ARS32Y03□
4.5 V DC ARS30Y4H□ ARS31Y4H□ ARS32Y4H□
9 V DC ARS30Y09□ ARS31Y09□ ARS32Y09□
12 V DC ARS30Y12□ ARS31Y12□ ARS32Y12□
24 V DC ARS30Y24□ ARS31Y24□ ARS32Y24□
Rated voltage Pick-up voltage*
(at 20°C 68°F)
Drop-out voltage*
(at 20°C 68°F)
Rated operating current
[±10%] (at 20°C 68°F)
Coil resistance
[±10%] (at 20°C 68°F)Rated operating power Max. allowable voltage
3 V DC
75%V or less of
rated voltage
(initial)
10%V or more of
rated voltage
(initial)
66.7 mA 45 Ω
200 mW
110%V (at 60°C 140°F)
150%V (at 20°C 68°F)
or less of rated voltage
4.5 V DC 44.4 mA 101.3Ω
9 V DC 22.2 mA 405 Ω
12 V DC 16.7 mA 720 Ω
24 V DC 8.3 mA 2,880 Ω
* Square, pulse drive (JIS C5442-1996)
Rated voltage Set voltage*
(at 20°C 68°F)
Reset voltage*
(at 20°C 68°F)
Rated operating current
[±10%] (at 20°C 68°F)
Coil resistance
[±10%] (at 20°C 68°F)Rated operating power Max. allowable voltage
3 V DC
75%V or less of
rated voltage
(initial)
75%V or less of
rated voltage
(initial)
66.7 mA 45 Ω
200 mW
110%V (at 60°C 140°F)
150%V (at 20°C 68°F)
or less of rated voltage
4.5 V DC 44.4 mA 101.3Ω
9 V DC 22.2 mA 405 Ω
12 V DC 16.7 mA 720 Ω
24 V DC 8.3 mA 2,880 Ω
* Square, pulse drive (JIS C5442-1996)
Rated voltage Set voltage*
(at 20°C 68°F)
Reset voltage*
(at 20°C 68°F)
Rated operating current
[±10%] (at 20°C 68°F)
Coil resistance
[±10%] (at 20°C 68°F)Rated operating power Max. allowable voltage
3 V DC
75%V or less of
rated voltage
(initial)
75%V or less of
rated voltage
(initial)
133.3 mA 22.5Ω
400 mW
110%V (at 60°C 140°F)
150%V (at 20°C 68°F)
or less of rated voltage
4.5 V DC 88.9 mA 50.6Ω
9 V DC 44.4 mA 202.5Ω
12 V DC 33.3 mA 360 Ω
24 V DC 16.7 mA 1,440 Ω
* Square, pulse drive (JIS C5442-1996)
RS (ARS)
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© Panasonic Corporation 2019 ASCTB106E 201903
2. Specications
* Measured the operation noise of the relay alone (with diodes at both ends of the coil) 30cm away from top side, by the A-weighted, FAST method while applying the rated
voltage.
Item Specications
Contact data
Arrangement 1 Form C
Contact resistance (initial) Max. 100 mΩ (By voltage drop 10 V AC 10mA)
Contact material Gold plating
Contact rating (resistive) 1W (at 3 GHz, Impedance: 50/75Ω, V.S.W.R.: Max. 1.4), 10 mA 24 V DC
Contact input power Max. 10W (at 3GHz, Impedance: 50/75Ω, V.S.W.R.: Max. 1.4)
Max. switching voltage 30 V DC
Max. switching current 0.5 A DC
High frequency
characteristics,
Impedance: 50Ω
(initial)
V.S.W.R. Max. 1.20/900MHz, Max. 1.40/3GHz (Standard PC board terminal)
Max. 1.20/900MHz, Max. 1.40/3GHz (Surface-mount terminal)
Insertion loss (without D.U.T. board’s loss) Max. 0.10dB/900MHz, Max. 0.35dB/3GHz (Standard PC board terminal)
Max. 0.20dB/900MHz, Max. 0.40dB/3GHz (Surface-mount terminal)
Isolation Min. 60dB/900MHz, Min. 35dB/3GHz (Standard PC board terminal)
Min. 55dB/900MHz, Min. 30dB/3GHz (Surface-mount terminal)
High frequency
characteristics,
Impedance: 75Ω
(initial)
V.S.W.R. Max. 1.15/900MHz, Max. 1.40/3GHz (Standard PC board terminal)
Max. 1.20/900MHz, Max. 1.50/3GHz (Surface-mount terminal)
Insertion loss (without D.U.T. board’s loss) Max. 0.10dB/900MHz, Max. 0.30dB/3GHz (Standard PC board terminal)
Max. 0.20dB/900MHz, Max. 0.50dB/3GHz (Surface-mount terminal)
Isolation Min. 60dB/900MHz, Min. 30dB/3GHz (Standard PC board terminal)
Min. 55dB/900MHz, Min. 30dB/3GHz (Surface-mount terminal)
Insulation resistance (initial) Min. 100MΩ (at 500V DC, Measured portion is the same as the case of dielectric voltage.)
Breakdown
voltage (initial)
Between open contacts 500 Vrms for 1min. (detection current: 10mA)
Between contact and earth terminal 500 Vrms for 1min. (detection current: 10mA)
Between contact and coil 1,000 Vrms for 1min. (detection current: 10mA)
Time
characteristics
Operate [Set] time (initial) Max. 10 ms [Max. 10 ms] (at 20°C 68°F, at rated voltage, without bounce)
Release [Reset] time (initial) Max. 6 ms [Max. 10 ms] (at 20°C 68°F, at rated voltage, without bounce, without diode)
Mechanical
characteristics
Shock
resistance
Functional Min. 196 m/s2 (half-sine shock pulse: 11 ms, detection time: 10µs)
Destructive Min. 980 m/s2 (half-sine shock pulse: 6 ms)
Vibration
resistance
Functional 10 to 55 Hz at double amplitude of 3 mm (detection time: 10µs)
Destructive 10 to 55 Hz at double amplitude of 5 mm
Operation noise*
(initial)
Standard type Approx. 40dB (at 20°C 68°F)
Quiet type (75Ω, PC board terminal type only) Approx. 30dB (at 20°C 68°F)
Expected life
Mechanical
Single side stable standard type Min. 5×106 (at 180 times/min.)
Single side stable quiet type Min. 106 (at 180 times/min.)
Latching type Min. 106 (at 180 times/min.)
Electrical
50Ω type
Min. 106 (Standard PC board terminal), Min. 3×105 (Surface-mount terminal)
(10V DC 10mA resistive)/Min. 3×105 (24V DC 10mA resistive)
Min. 106 (Standard PC board terminal), Min. 3×105 (Surface-mount terminal)
(1W, at 3GHz, Impedance: 50Ω, V.S.W.R: Max. 1.4) (at 20 times/min.)
75Ω type Min. 3×105 (10mA 24V DC resistive)
Min. 3×105 (1W, at 3GHz, Impedance: 75Ω, V.S.W.R: Max. 1.4) (at 20 times/min.)
Conditions Conditions for operation, transport and storage
Ambient temperature: –40 to 70°C –40°F to 158°F
(Single side stable standard and Latching type)
Ambient temperature: –40 to 60°C –40°F to 140°F (Single side stable quiet type)
Humidity: 5 to 85% R.H. (Not freezing and condensing at low temperature)
Unit weight Approx. 2 g .071 oz
RS (ARS)
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industrial.panasonic.com/ac/e/ © Panasonic Corporation 2019 ASCTB106E 201903
REFERENCE DATA
1.-(1) High frequency characteristics (Impedance: 50Ω, Standard PC board terminal)
Sample: ARS144H; Measuring method: Measured with Agilent Technologies network analyzer (E8363B). *For details, see “8. Measuring method” under “NOTES”.
• V.S.W.R. characteristics • Isolation characteristics
• Insertion loss characteristics
(without D.U.T. board’s loss)
1.-(2) High frequency characteristics (Impedance: 75Ω, Standard PC board terminal)
Sample: ARS104H; Measuring method: Measured with Agilent Technologies network analyzer (E8363B). *For details, see “8. Measuring method” under “NOTES”.
1.-(3) High frequency characteristics (Impedance: 50Ω, Surface-mount terminal)
Sample: ARS14A4H; Measuring method: Measured with Agilent Technologies network analyzer (E8363B). *For details, see “8. Measuring method” under “NOTES”.
0.3MHz 900MHz 3GHz
1.5
2.0
1.0
NC
NO
Frequency
V.S.W.R.
Standard value
Reference value
NC
NO
1.0
0
0.5
0.3MHz 900MHz 3GHz
Frequency
Insertion loss, dB
Reference value
Standard value
100
0
50
0.3MHz 900MHz 3GHz
NC
NO
Frequency
Isolation, dB
Reference value
Standard value
• V.S.W.R. characteristics • Isolation characteristics• Insertion loss characteristics
(without D.U.T. board’s loss)
0.3MHz 900MHz 3GHz
1.5
2
1
NC
NO
Frequency
V.S.W.R.
Standard value
Reference value
NC
NO
1.0
0
0.5
0.3MHz 900MHz 3GHz
Frequency
Insertion loss, dB
Standard value
Reference value
100
0
50
0.3MHz 900MHz 3GHz
NO
NC
Frequency
Isolation, dB
Reference value
Standard value
• V.S.W.R. characteristics • Isolation characteristics• Insertion loss characteristics
(without D.U.T. board’s loss)
0.3MHz 900MHz 3GHz
1.5
2.0
1
NC
NO
Frequency
V.S.W.R.
Standard value
Reference value
NC
NO
1.0
0
0.5
0.3MHz 900MHz 3GHz
Frequency
Insertion loss, dB
Standard value
Reference value
100
0
50
0.3MHz 900MHz 3GHz
NO
NC
Frequency
Isolation, dB
Standard value
Reference value
1.-(4) High frequency characteristics (Impedance: 75Ω, Surface-mount terminal)
Sample: ARS10A4H; Measuring method: Measured with Agilent Technologies network analyzer (E8363B). *For details, see “8. Measuring method” under “NOTES”.
• V.S.W.R. characteristics • Isolation characteristics• Insertion loss characteristics
(without D.U.T. board’s loss)
0.3MHz 900MHz 3GHz
1.5
2.0
1.0
NC
NO
Frequency
V.S.W.R.
Standard value
Reference value
NC
NO
1.0
0
0.5
0.3MHz 900MHz 3GHz
Frequency
Insertion loss, dB
Standard value
Reference value
100
0
50
0.3MHz 900MHz 3GHz
NC
NO
Frequency
Isolation, dB
Standard value
Reference value
RS (ARS)
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© Panasonic Corporation 2019 ASCTB106E 201903
2.-(1) Operation noise distribution
Sample: ARS134H (single side stable quiet type),
50 pcs.
Coil voltage: rated voltage applied (with diode)
Equipment setting: A weighted sound pressure level,
FAST.
Background noise: approx. 20 dB
Method of measurement: See gure below.
When releasedWhen operated
0
10
20
30
20 30 40 50
Quantity, n
Noise level, dB
0
10
20
30
20 30 40 50
Quantity, n
Noise level, dB
2.-(2) Operation noise distribution
Sample: ARS104H (single side stable standard type),
50 pcs.
Coil voltage: rated voltage applied (with diode)
Equipment setting: A weighted sound pressure level,
FAST.
Background noise: approx. 20 dB
Method of measurement: See gure below.
When releasedWhen operated
Relay
Acoustic absorption mat
11.811inch
300mm
Microphone
Top of relay
0
10
20
30
20 30 40 50
Quantity, n
Noise level, dB
0
10
20
30
20 30 40 50
Quantity, n
Noise level, dB
Relay
Acoustic absorption mat
11.811inch
300mm
Microphone
Top of relay
2.-(3) Operation noise distribution
Sample: ARS114H (latching type), 50 pcs.
Coil voltage: rated voltage applied (with diode)
Equipment setting: A weighted sound pressure level,
FAST.
Background noise: approx. 20 dB
Method of measurement: See gure below.
When set and reset
Relay
Acoustic absorption mat
11.811inch
300mm
Microphone
Top of relay
0
10
20
30
20 30 40 50
Quantity, n
Noise level, dB
DIMENSIONS (mm inch)The CAD data of the products with a CAD Data mark can be downloaded from https://industrial.panasonic.com/ac/e/
CAD Data
Tolerance: ±0.1 ±.004
1. 50Ω type
<Standard PC board terminal>
External dimensions PC board pattern (Bottom view)
Tolerance: ±0.3 ±.012
2 coil latching only
8-1.00 dia.
8-.039 dia.
2.54
.100
6.35
.250
1.406.35
.055.250
3.50 7.20
.138 .283
2.54
.100
2 coil latching only
Stand off
2-0.60×0.20
2-.024×.008
(0.60)
(.024)
3-0.40×0.20
3-.016×.008
3-□0.45
3-□.018
8.60
.339
14.00
.551
3-2.50
(Contact terminal)
+0.5
-0.1
3-.098+.020
-.004
RS (ARS)
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industrial.panasonic.com/ac/e/ © Panasonic Corporation 2019 ASCTB106E 201903
CAD Data
Tolerance: ±0.3 ±.012
<Standard contact type>
2. 75Ω type
14.00
.551
8.60
.339
3-□0.45
3-□.018
3-0.40×0.20
3-.016×.008
(1.40)
(.055)
2-1.40×0.20
2-.055×.008
Stand off
2 coil latching only
2.54
.100
7.20
.283
3.50
.138
6.35 1.40
.250 .055
3-2.50
(Contact terminal)
+0.5
-0.1
3-.098+.020
-.004
6.35
.250
2.54
.100
3-0.90 dia.
3-.035 dia.
3-0.70 dia. Min.
3-.028 dia. Min.
1.80
.071
0.80
.031
2 coil latching only
R0.40
R.016
External dimensions PC board pattern (Bottom view)
Tolerance: ±0.1 ±.004
Schematic (Bottom view)
<Reversed contact type>
10 6
51
9 78
+
Direction indication
51
+
69 8 710
Direction indication
4
810 7
1
+
5
9 6
+
Direction indication
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
10 6
51
9 78
+
Direction indication
51
+
69 8 710
Direction indication
4
810 7
1
+
5
9 6
+
Direction indication
<Surface-mount terminal>
1) E layout
1. Impedance: 50Ω type
External dimensions PC board pattern (Top view)
6-1.10
8-0.80
3.30 1.27
3.30
6.86
10.16
13.46
6-.043
8-.031
.130 .050
.130
.270
.400
.530
1.50 1.50
11.70
.059 .059
.461
Tolerance: ±0.3 ±.012
<Standard contact type>
Tolerance: ±0.1 ±.004
Schematic (Top view)
<Reversed contact type>
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
2
+-
7
68
4
18 17 13
14
15 11 1016 12
Direction indication
-++
18 17 13
14
27
68
4
15 11 1016 12
Direction indication
12 10
11
15
48
14 13
6
17
7
16
+
-
2
18
Direction indication
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
27
68
4
18 17 13
14
15 11 1016 12
-+
Direction indication
27
68
4
-
+
18 17 13
14
15 11 1016 12
Direction indication
27
68
4
18 17 13
14
15 11 1016 12
-++
Direction indication
10.16
.400
0.5
0.5
0.5
.020
0.6
3.2
.126
0.6
8-0.4
8-.016
10.16
.400
.126
8.6
.339
14.6
.575
3.2
.024
3.2
0.6
3.2
.024
.024
.126
.126
11.2
.441
14.0 .551
9.2
.362
1.27
.020
.020
.050
8.0
.315
.006
0.15 .006
0.15
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2) Y layout
Tolerance: ±0.3 ±.012
<Standard contact type>
External dimensions PC board pattern (Top view)
Tolerance: ±0.1 ±.004
<Reversed contact type>
Schematic (Top view)
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
12 10
11
15
45 8
13
6
17
7
16
+
-2
18
Direction indication
2
+-
5 7
68
4
18 17 1315 11 1016 12
Direction indication
-++
18
5
17 13
27
68
4
15 11 1016 12
Direction indication
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
5
27
68
4
18 17 1315 11 1016 12
-+
Direction indication
5
27
68
4
-
+
18 17 1315 11 1016 12
Direction indication
5
27
68
4
18 17 1315 11 1016 12
-++
Direction indication
1) E layout
2-0.90
3-1.00
9-0.80
1.273.20
3.30
6.86
13.46
1.95 1.95
10.16
2-.035
3-.039
9-.031
.050.126
.130
.270
.530
.400
11.70
.077 .077
.461
10.16
.400
0.5
0.5
0.5
.020
0.6
3.2
.126
0.6
8-0.4
8-.016
10.16
.400
.126
8.6
.339
14.6
.575
3.2
.024
3.2
0.6
3.2
.024
.024
.126
.126
11.2
.441
14.0 .551
9.2
.362
1.27
.020
.020
.050
8.0
.315
.006
0.15 .006
0.15
2. Impedance: 75Ω type
Tolerance: ±0.3 ±.012
<Standard contact type>
External dimensions PC board pattern (Top view)
Tolerance: ±0.1 ±.004
<Reversed contact type>
Schematic (Top view)
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
12 10
11
15
45 8
13
6
17
7
16
+
-2
18
Direction indication
2
+-
5 7
68
4
18 17 1315 11 1016 12
Direction indication
-++
18
5
17 13
27
68
4
15 11 1016 12
Direction indication
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
5
27
68
4
18 17 1315 11 1016 12
-+
Direction indication
5
27
68
4
-
+
18 17 1315 11 1016 12
Direction indication
5
27
68
4
18 17 1315 11 1016 12
-++
Direction indication
13.46
10.16
6.86
3.30
1.27
3.30
8-0.80
6-1.10
.530
.400
.270
.130
.050
.130
8-.031
6-.043
1.50 1.50
11.70
.059 .059
.461
10.16
0.6
10.16
8.6
14.6
3.2
3.2
.024
.126
.126
0.6
.024
.400
.400
.575
14.0 .551
.006
0.15 .006
0.15
.339
11.2
.441
9.2
.362
8.0
.315
0.5
0.5
1.27
.020
.020
.050
0.5
.020
3.2
.126
8-0.4
8-.016
.126
.024
3.2
0.6
RS (ARS)
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0.80
11.70
10.16
1.951.95
.461
.077.077
13.46
6.86
3.30
3.20 1.27
8-0.80
3-1.00
2-0.90
.031
.400
.530
.270
.130
3.20 .050
8-.031
3-.039
2-.035
2) Y layout
Tolerance: ±0.3 ±.012
<Standard contact type>
External dimensions PC board pattern (Top view)
Tolerance: ±0.1 ±.004
<Reversed contact type>
Schematic (Top view)
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
12 10
11
15
45 8
13
6
17
7
16
+
-2
18
Direction indication
2
+-
5 7
68
4
18 17 1315 11 1016 12
Direction indication
-++
18
5
17 13
27
68
4
15 11 1016 12
Direction indication
Single side stable type
(Deenergized condition)
1 coil latching type
(Reset condition)
2 coil latching type
(Reset condition)
5
27
68
4
18 17 1315 11 1016 12
-+
Direction indication
5
27
68
4
-
+
18 17 1315 11 1016 12
Direction indication
5
27
68
4
18 17 1315 11 1016 12
-++
Direction indication
10.16
0.6
10.16
8.6
14.6
3.2
3.2
.024
.126
.126
0.6
.024
.400
.400
.575
14.0 .551
.006
0.15 .006
0.15
.339
11.2
.441
9.2
.362
8.0
.315
0.5
0.5
1.27
.020
.020
.050
0.5
.020
3.2
.126
8-0.4
8-.016
.126
.024
3.2
0.6
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NOTES
1. Coil operating power
Pure DC current should be applied to the
coil. The wave form should be
rectangular. If it includes ripple, the ripple
factor should be less than 5%.
However, check it with the actual circuit
since the characteristics may be slightly
di󰀨erent. The nominal operating voltage
should be applied to the coil for more
than 30 ms to set/reset the latching type
relay.
2. Coil connection
When connecting coils, refer to the wiring
diagram to prevent mis-operation or
malfunction.
3. External magnetic eld
Since RS relays are highly sensitive
polarized relays, their characteristics will
be a󰀨ected by a strong external magnetic
eld. Avoid using the relay under that
condition.
4. Cleaning
For automatic cleaning, the boiling
method is recommended. Avoid
ultrasonic cleaning which subjects the
relays to high frequency vibrations, which
may cause the contacts to stick.
It is recommended that alcoholic solvents
be used.
5. Conditions for operation, transport
and storage conditions
1) Temperature
• Single side stable standard and latching
type: –40 to 70°C –40 to 158°F
• Single side stable quiet type:
–40 to 60°C –40 to 140°F
2) Humidity: 5 to 85% RH
(Avoid freezing and condensation.)
The humidity range varies with the
temperature. Use within the range
indicated in the graph below.
3) Atmospheric pressure: 86 to 106 kPa
Temperature and humidity range for
usage, transport, and storage:
Single side stable standard
and latching type
*Relays are inuenced by the type of PC
board used. Please conrm with the
actual PC board you plan to use.
*Please avoid reow soldering.
2) Surface-mount terminal
In case of automatic soldering, the
following conditions should be observed
(1) Position of measuring temperature
Single side stable quiet
and latching type
4) Condensation
Condensation forms when there is a
sudden change in temperature under
high temperature and high humidity
conditions. Condensation will cause
deterioration of the relay insulation.
5) Freezing
Condensation or other moisture may
freeze on the relay when the temperature
is lower than 0°C 32°F. This causes
problems such as sticking of movable
parts or operational time lags.
6) Low temperature, low humidity
environments
The plastic becomes brittle if the relay is
exposed to a low temperature, low
humidity environment for long periods of
time.
7) Storage requirements
Since the relay is sensitive to humidity,
the surface-mount type is packaged with
tightly sealed anti-humidity packaging.
However, when storing, please be careful
of the following.
(1) Please use promptly once the
antihumidity pack is opened.
If relays are left as is after unpacking,
they will absorb moisture which will result
in loss of air tightness as a result of case
expansion due to thermal stress when
reow soldering during the mounting
process. (within one day, 30°C and
60%R.H or less)
(2) When storing for a log period after
opening the anti-humidity pack, storage
in anti-humidity packaging with an
antihumidity
bag to which silica gel has been
added, is recommended.
*Furthermore, if the relay is solder
mounted when it has been subjected to
excessive humidity, cracks and leaks can
occur. Be sure to mount the relay under
the required mounting conditions.
6. Soldering
1) Please meet the following conditions if
this relay is to be automatically soldered.
(1) Preheating: Max. 120°C 248°F
(terminal solder surface) for max. 120
seconds
(2) Soldering: Max. 260±5°C 500±9°F for
max. 6 seconds
Humidity, %R.H.
Temperature, °C °F
Tolerance range
85
5
0 70-40 32 158-40
(Avoid
condensation
when used at
temperatures
higher than
0°C 32°F)
(Avoid freezing
when used at
temperatures
lower than
0°C 32°F)
Humidity, %R.H.
Temperature, °C °F
Tolerance range
85
5
0 60-40 32 140-40
(Avoid
condensation
when used at
temperatures
higher than
0°C 32°F)
(Avoid freezing
when used at
temperatures
lower than
0°C 32°F)A
A: Surface of PC board where relay is mounted.
(2) IR (infrared reow) soldering method
• Mounting cautions
Rise in relay temperature depends
greatly on the component mix on a given
PC board and the heating method of the
reow equipment. Therefore, please test
beforehand using actual equipment to
ensure that the temperature where the
relay terminals are soldered and the
temperature at the top of the relay case
are within the conditions given above.
3) Please meet the following conditions if
this relay is to be soldered by hand.
(1) 260°C 500°F for max. 10 seconds
(2) 350°C 662°F for max. 3 seconds
The e󰀨ect on the relay depends on the
actual substrate used. Please verify the
substrate to be used.
(3) Avoid ultrasonic cleaning. Doing so
will adversely a󰀨ect relay characteristics.
Please use alcohol-based cleaning
solvents when cleaning relays.
7. Tape and reel packing
1) Tape dimensions
T1
T2
T3
t1t2
T1=150 to 180°C
T2=230°C and higher
T3=250°C max.
t1=60s to 120s
t2=within 30s
8.6
.339
8.3
.327
Relay polarity bar
RS relay .630
16.0 .079
2.0
0.4
.016
4.0
.157
Tape coming out direction
Z type
X type
(General tolerance: ±0.1 ±.004)
.472
12.0
24.0±0.3
.945±.012
.069
1.75
11.5
.453
15.00
.591
dia..059+.004
0
dia.1.5+0.1
0
±0.2
24.4+2.0
0
.961+.079
0
2.0
±.008
.079
13 dia.
±0.2
.512 dia.
±.008
.827 dia.
±.031
21 dia.
±0.8
80 dia.
±1
3.150 dia.
±.039
380 dia.
±2
14.961 dia.
±.079
.079±.020
2.0±0.5
2) Dimensions of plastic reel
RS (ARS)
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8. Measuring method
1) 50Ω type
Connect connectors 1 and 2 respectively
to PORT 1 and PORT 2. Perform
calibration using the 3.5 mm calibration
kit (HP85052B).
After calibration, connect the D.U.T.
board and measure. However,
connectors other than those for
measurement should be connected with
a 50Ω termination resistor.
<Standard PC board terminal>
PC board
Dimensions (mm inch)
Material: Glass PTFE double-sided
through hole PC board R-4737
(manufactured by our company)
Board thickness: t = 0.8 mm .031 inch
Copper plating: 18 μm
Connector (SMA type)
Product name: 01K1808-00 (Waka
Manufacturing Co., Ltd.)
Insertion loss compensation:
The insertion loss of relay itself is given
by subtracting the insertion loss of
shortcircuit the Com and the NC (or NO).
(signal path and two connectors)
PORT2
PORT1
Network
analyzer
Agilent
Technologies
E8363B
1 2
1 2
No. Product name Contents
1Agilent 85130-
60011
Adapter
2.4mm-3.5mm female
.095inch-.138inch female
2SUHNER
SUCOFLEX104
Cable
3.5mm-3.5mm male
.138inch-.138inch male
20.00
.787
10.16
.400
5.08
.200
2.54
.100
6.35
.250
4.20
.165
13.00
1.80
.071
2.80
.512
.110
3-R 1.40
3-R .055
3-R 0.90
3-R .35
8-1.00 dia.
8-.039 dia.
(Through hole)
5-2.00 dia.
5-1.40 dia.
5-.079 dia.
5-.055 dia.
<Surface-mount terminal and
E layout>
PC board
Dimensions (mm inch)
<Surface-mount terminal and
Y layout>
PC board
Dimensions (mm inch)
PC board for correction
Dimensions (mm inch)
2.80
.110
1.80
.071
9.12
.359
1.27
.050
20.00
.787
10.16
.400 2.50
.098
2.50
.098 1.80
.071
1.80
2.50
2.80
.071
.098
.110
2.80
.110
1.80
.071
.146
3.70
6.05
.238
15.15
.596
15.95
.628
22.00
.866
1.27
.050
20.00
.787
10.16
.400 2.80
2.50
2.50
.098 1.80
.110
.098
.071
1.80
.071
2.80
.110
1.80
.071
3.70
.146 6.05
.238
22.00
15.15
.866
.596
2) 75Ω type
Network
analyzer
PORT2
PORT1
Agilent
Technologies
E8363B
1
1 2
2
Connect connectors 1 and 2 respectively
to PORT 1 and PORT 2. Perform
calibration using the 3.5 mm calibration
kit (HP85039B).
No. Product name Contents
1 85134-60003 Test port cable
2 11852B
Conversion adapter;
50Ω N type (female) to
75Ω N type (male)
2 85039-60011
Conversion adapter;
75Ω N type (female) to
75Ω F type (male)
After calibration, connect the D.U.T.
board and measure. However,
connectors other than those for
measurement should be connected with
a 75Ω termination resistor.
<Standard PC board terminal>
PC board
Dimensions (mm inch)
5.08
.200
.070
1.78
2.54
.100
20.00
.787
10.16
.400
3-1.00 dia.
3-3.00 dia.
3-.028 dia.
3-0.70 dia.
3-0.55 dia.
3-1.50 dia.
3-.059 dia.
3-.022 dia.
(Through hole)
3-.118 dia.
3-.039 dia.
0.80
.031
R0.40
R.016
6.35
.250
4.20
.165
.035
0.90
.193
4.90
13.00
.512
<Surface-mount terminal and
E layout>
PC board
Dimensions (mm inch)
1.27
.050
20.00
.787
10.16
.400 2.80
2.50
2.50
.098 0.80
.110
.098
.031
0.80
.031
2.80
.110
0.80
.031
4.70
.185 7.75
.305
16.15
.636
24.00
.945
<Surface-mount terminal and
Y layout>
PC board
Dimensions (mm inch)
1.27
.050
20.00
.787
10.16
.400
2.80
2.50
2.50
.098 2.50
.098
0.80
.110
.098
.031
0.80
.031
2.80
.110
0.80
.031
.185
4.70
7.75
.305
16.15
.636
.640
16.25
24.00
.945
PC board for correction
Dimensions (mm inch)
4.90
.193 0.90
.035
9.12
.359
Material: Glass PTFE double-sided
through hole PC board R-4737
(manufactured by our company)
Board thickness: t = 0.8 mm .031 inch
Copper plating: 18μm
Connector (F type receptacle)
Product name: C05-0236 (Komine
Musen Electric Corporation)
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Insertion loss compensation:
The insertion loss of relay itself is given
by subtracting the insertion loss of
shortcircuit the COM and the NC (or NO).
(signal path and two connectors)
9. Others
1) The switching lifetime is dened under
the standard test condition specied in
the JIS* C 5442 standard (temperature
15 to 35°C 59 to 95°F, humidity 25 to
75%). Check this with the real device as it
is a󰀨ected by coil driving circuit, load
type, activation frequency, activation
phase, ambient conditions and other
factors.
Also, be especially careful of loads such
as those listed below.
• When used for AC load-operating and
the operating phase is synchronous,
rocking and fusing can easily occur due
to contact shifting.
• When high-frequency opening and
closing of the relay is performed with a
load that causes arcs at the contacts,
nitrogen and oxygen in the air is fused by
the arc energy and HNO3 is formed. This
can corrode metal materials.
6) To ensure accurate operation of the
latching type amidst surrounding
temperature changes and other factors
that might a󰀨ect the set and reset pulse
times, we recommend a coil impress set
and reset pulse width of at least 30 ms at
the rated operation voltage.
7) The latching type relay is shipped in
the reset position. But jolts during
transport or impacts during installation
can change the reset position. It is,
therefore, advisable to build a circuit in
which the relay can be initialized (set and
reset) just after turning on the power.
8) If silicone materials (e.g., silicone
rubbers, silicone oils, silicone coating
agents, silicone sealers) are used in the
vicinity of the relay, the gas emitted from
the silicone may adhere to the contacts of
the relay during opening and closing and
lead to improper contact. If this is the
case, use a material other than silicone.
Three countermeasures for these are
listed here.
(1) Incorporate an arc-extinguishing
circuit.
(2) Lower the operating frequency
(3) Lower the ambient humidity
2) Use the relay within specications
such as coil rating, contact rating and on/
o󰀨 service life. If used beyond limits, the
relay may overheat, generate smoke or
catch re.
3) Be careful not to drop the relay. If
accidentally dropped, carefully check its
appearance and characteristics before
use.
4) Be careful to wire the relay correctly.
Otherwise, malfunction, overheat, re or
other trouble may occur.
5) If a relay stays on in a circuit for many
months or years at a time without being
activated, circuit design should be
reviewed so that the relay can remain
non-excited. A coil that receives current
all the time heats, which degrades
insulation earlier than expected. A
latching type relay is recommended for
such circuits.
Please refer to "the latest product specications"
when designing your product.
• Requests to customers :
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c
GUIDELINES FOR MICROWAVE DEVICES USAGE
Precautions for Coil Input
For cautions for use, please read “GUIDELINES FOR RELAY USAGE”.
https://industrial.panasonic.com/ac/e/control/relay/cautions_use/index.jsp
Long term current carrying
A circuit that will be carrying a current continuously for long periods
without relay or microwave device switching operation. (circuits for
emergency lamps, alarm devices and error inspection that, for
example, revert only during malfunction and output warnings with form
B contacts) Continuous, long-term current to the coil will facilitate
deterioration of coil insulation and characteristics due to heating of the
coil itself.
For circuits such as these, please use a magnetic-hold type latching
relay. If you need to use a single stable relay, use a sealed type relay
that is not easily a󰀨ected by ambient conditions and make a failsafe
circuit design that considers the possibility of contact failure or
disconnection.
DC Coil operating power
Steady state DC current should be applied to the coil. The wave form
should be rectangular. If it includes ripple, the ripple factor should be
less than 5%.
However, please check with the actual circuit since the electrical
characteristics may vary. The rated coil voltage should be applied to
the coil and the set/reset pulse time of latching type relay di󰀨ers for
each relays, please refer to the relay's individual specications.
Coil connection
When connecting coils of polarized relays, please check coil polarity
(+,-) at the internal connection diagram (Schematic). If any wrong
connection is made, it may cause unexpected malfunction, like
abnormal heat, re and so on, and circuit do not work. Avoid
impressing voltages to the set coil and reset coil at the same time.
Maximum allowable voltage and temperature rise
Proper usage requires that the rated coil voltage be impressed on the
coil. Note, however, that if a voltage greater than or equal to the
maximum continuous voltage is impressed on the coil, the coil may
burn or its layers short due to the temperature rise. Furthermore, do
not exceed the usable ambient temperature range listed in the catalog.
Maximum allowable voltage for coil
In addition to being a requirement for relay operation stability, the
maximum continuous impressed coil voltage is an important constraint
for the prevention of such problems as thermal deterioration or
deformity of the insulation material, or the occurrence of re hazards.
Temperature rise due to pulse voltage
When a pulse voltage with ON time of less than 2 minutes is used, the
coil temperature rise bares no relationship to the ON time. This varies
with the ratio of ON time to OFF time, and compared with continuous
current passage, it is rather small. The various relays are essentially
the same in this respect.
Operate voltage change due to coil temperature rise 
 (Hot start)
In DC relays, after continuous passage of current in the coil, if the
current is turned OFF, then immediately turned ON again, due to the
temperature rise in the coil, the pick-up voltage will become somewhat
higher. Also, it will be the same as using it in a higher temperature
atmosphere. The resistance/temperature relationship for copper wire
is about 0.4% for 1°C, and with this ratio the coil resistance increases.
That is, in order to operate of the relay, it is necessary that the voltage
be higher than the pick-up voltage and the pick-up voltage rises in
accordance with the increase in the resistance value. However, for
some polarized relays, this rate of change is considerably smaller.
Current passage time (%)
For continuousu passage Tempereture rise value is
100
%
ON : OFF =
3
:
1
About
80
%
ON : OFF =
1
:
1
About
50
%
ON : OFF =
1
:
3
About
35
%
ON : OFF = 1 : 1
Voltage
Time
Ambient Environment
Dew condensation
Condensation occurs when the ambient temperature drops suddenly
from a high temperature and humidity, or the relay and microwave
device is suddenly transferred from a low ambient temperature to a
high temperature and humidity. Condensation causes the failures like
insulation deterioration, wire disconnection and rust etc.
Panasonic Corporation does not guarantee the failures caused by
condensation.
The heat conduction by the equipment may accelerate the cooling of
device itself, and the condensation may occur.
Please conduct product evaluations in the worst condition of the actual
usage. (Special attention should be paid when high temperature
heating parts are close to the device. Also please consider the
condensation may occur inside of the device.)
Icing
Condensation or other moisture may freeze on relays when the
temperature become lower than 0°C.This icing causes the sticking of
movable portion, the operation delay and the contact conduction failure
etc. Panasonic Corporation does not guarantee the failures caused by
the icing.
The heat conduction by the equipment may accelerate the cooling of
relay itself and the icing may occur. Please conduct product
evaluations in the worst condition of the actual usage.
Low temperature and low humidity
The plastic becomes brittle if the switch is exposed to a low
temperature, low humidity environment for long periods of time.
High temperature and high humidity
Storage for extended periods of time (including transportation periods)
at high temperature or high humidity levels or in atmospheres with
organic gases or sulde gases may cause a sulde lm or oxide lm to
form on the surfaces of the contacts and/or it may interfere with the
functions. Check out the atmosphere in which the units are to be
stored and transported.
Package
In terms of the packing format used, make every e󰀨ort to keep the
e󰀨ects of moisture, organic gases and sulde gases to the absolute
minimum.
ASCTB403E 201905
Panasonic Corporation Electromechanical Control Business Division
industrial.panasonic.com/ac/e/ Panasonic Corporation 2019
c
GUIDELINES FOR MICROWAVE DEVICES USAGE
Storage requirements
Since the SMD type is sensitive to humidity it is packaged with tightly
sealed anti-humidity packaging. However, when storing, please be
careful of the following.
1) Please use promptly once the anti-humidity pack is opened.(within
72 hours, Max. 30°C/70% R.H.). If left with the pack open, the relay
will absorb moisture which will cause thermal stress when reow
mounting and thus cause the case to expand. As a result, the seal
may break.
* For RE relays, after this bag is opened, the product must be used
within 24 hours.
2) If relays will not be used within 72 hours, please store relays in a
humidity controlled desiccator or in an anti-humidity bag to which
silica gel has been added.
* If the relay is to be soldered after it has been exposed to excessive
humidity atmosphere, cracks and leaks can occur. Be sure to mount
the relay under the required mounting conditions
* For RE relays, after this bag is opened, the product must be used
within 24 hours.
3) The following cautionary label is a󰀩xed to the anti-humidity pack.
Silicon
When a source of silicone substances (silicone rubber, silicone oil,
silicone coating materials and silicone lling materials etc.) is used
around the relay, the silicone gas (low molecular siloxane etc.) may be
produced.
This silicone gas may penetrate into the inside of the relay. When the
relay is kept and used in this condition, silicone compound may adhere
to the relay contacts which may cause the contact failure. Do not use
any sources of silicone gas around the relay (Including plastic seal
types).
NOx Generation
When relay is used in an atmosphere high in humidity to switch a load
which easily produces an arc, the NOx created by the arc and the
water absorbed from outside the relay combine to produce nitric acid.
This corrodes the internal metal parts and adversely a󰀨ects operation.
Avoid use at an ambient humidity of 85%RH or higher (at 20°C). If use
at high humidity is unavoidable, please contact our sales
representative.
Others
Cleaning
1) Although the environmentally sealed type relay (plastic sealed type,
etc.) can be cleaned, avoid immersing the relay into cold liquid (such
as cleaning solvent) immediately after soldering. Doing so may
deteriorate the sealing performance.
2) Surface mount terminal type relay is sealed type and it can be
cleaned by immersion. Use pure water or alcohol-based cleaning
solvent.
3) Cleaning with the boiling method is recommended (The temperature
of cleaning liquid should be 40°C or lower).
Avoid ultrasonic cleaning on relays. Use of ultrasonic cleaning may
cause breaks in the coil or slight sticking of the contacts due to the
ultrasonic energy.
Other handling precautions
Expected switching life is dened under the standard test conditions
(temperature 15 to 35°C, humidity: 25 to 75%) specied in JIS C
5442.
Expected switching life is depend on usage conditions; coil driving
circuit, load type, activation frequency, activation phase, ambient
conditions and other factors. Please check relays and microwave
devices on the actual circuit.
Also, pay special attention loads such as those listed below.
When used for AC load-operating and the operating phase is
synchronous, rocking and fusing can easily occur due to contact
shifting.
Frequent switching under load condition
When high frequently switched under load condition that can cause
arc at the contacts, nitrogen and oxygen in the air is fused by the
arc energy and HNO3 is formed. This can corrode metal materials.
Countermeasures for these are.
1. Incorporate an arc-extinguishing circuit.
2. Lower the operating frequency
3. Lower the ambient humidity
When used for ‘‘Dry switching’ without load current, please contact
our sales representative.
Please avoid relays to be used outside of the specication ranges
such as the coil rating, contact rating and switching life that may
cause abnormal heating, smoke, and re.
In case relays and microwave devices are dropped, please do not
use.
Please refer to "the latest product specications"
when designing your product.
•Requests to customers:
https://industrial.panasonic.com/ac/e/salespolicies/
*RE Relays only
ASCTB403E 201905
Please contact ..........
Electromechanical Control Business Division
industral.panasonic.com/ac/e/
Specifications are subject to change without notice.
1006, Oaza Kadoma, Kadoma-shi, Osaka 571-8506, Japan
©Panasonic Corporation 2019
ASCTB106E 201907