EE2 Series, 3-24 VDC

Miniature Signal Relays
EC2/EE2 Series
Overview
Applications
The KEMET EC2/EE2 miniature signal relays offer a compact
case size in a slim package. Minimal board space is consumed
with either a through-hole or surface mount configuration. These
relays are recognized by UL and CSA, while also being compliant
with Part 68 of the FCC’s 1,500 V surge capacity.
• Electronic switching systems
•PBX
• Terminal equipment
• Telephone systems
Benefits
•
•
•
•
•
•
•
Low power consumption (< 200 mW)
Compact and lightweight
Low magnetic interference
Tube or embossed tape and reel packaging
UL recognized (E73266) and CSA certified (LR46266)
Surface mount and through-hole options
High Breakdown Voltage (NKX) type can withstand 1.5 kVAC at
open contacts
Part Number System
EE2-
3
S
NU
-L
Series
Coil Voltage
Latch Type
Lead Type
Packaging
EC2- = Through-hole mount
EE2- = Surface mount
3 = 3 VDC
4.5 = 4.5 VDC
5 = 5 VDC
12 = 12 VDC
24 = 24 VDC
Blank = Non-latch type
S = Single coil latch type
T = Double coil latch type
NU = Standard
NUH = Minimum footprint
NUX = High solder joint reliability
NKX = High breakdown voltage and
high solder joint reliability
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
Blank = Tube
-L = Embossed tape on reel
One world. One KEMET
R7002_EC2_EE2 • 2/27/2014
1
Miniature Signal Relays – EC2/EE2 Series
B Maximum
D Maximum
Dimensions – Millimeters
H Maximum
EC2 Series
Non-latch type and single coil latch type
0.5
K
0.25B Maximum
D Maximum
5.08 P1 P1
0.5
K
H Maximum
Double coil latch type
0.5
P2
H Maximum
B Maximum
D Maximum
K
D Maximum
5.08 P1 P1 P1
0.25
P2
K
P2
Double coil latch type
B Maximum
D Maximum
B Maximum
D Maximum
H Maximum
H Maximum
0.25
0.5
D Maximum
5.08 P1 P1
K
B Maximum
P2
Series
D
5.08 P1 P115.0
EC2 (NU)
EE2 (NU)
EE2 (NUH)
EE2 (NUX, NKX)
15.0
15.0
15.0
K
H
9.4
10.0
10.0
10.35
0.25
B
7.5
7.5
7.5
7.5
P2
P3
0.25
0.5
D Maximum
5.08 P1 P1 P1
P3
H Maximum
0.5
0.25
5.08 P1 P1 P1
EE2 Series
Non-latch type and single coil latch type
P2
H Maximum
0.5
5.08 P1 P1
0.25B Maximum
K
H Maximum
P1
2.54
2.54
2.54
2.54
0.5
P2
5.08
5.08
5.08
5.08
P3
K
5.08
— P1 P13.2P1
9.5
7.5
9.0
1.0
1.0
1.35
B Maximum
P2
P3
0.25
K
P2
P3
General tolerance: ±0.2
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
2
Miniature Signal Relays – EC2/EE2 Series
Pin Configurations
Bottom view
Single coil latch type
(Reset position)
Non-latch type
(Non-energized position)
4
5
1
+
-
12
10
9
3
4
1
5
+-
Direction mark
3
Direction mark
Direction mark
1
Double coil latch type
(Reset position)
SR
- +
8
12
10
9
DirectionULmark
(pin No. 1 and 10)
CSA
1
Mark
UL, CSA marking
Spacing:
UL114, mark
UL478
Direction
(pin No. 1 and 10)
Certification
Body
TUV
Mark
-
12
0501F
Set coil
File Number
UL Recognized
(UL508)1 Country
CSA Certified
(CSA
JAPAN 22.2 #14)
Date code
0501F
9
8
7
Reset coil
Rating
E73266
of origin
30 VDC, 2 A (resistive)
110 VDC, 0.3 A (resistive)
125 VAC, 0.5 A (resistive)
LR46266
Country of origin
Specification
NU, NUH, NUX
(Non-latch and Single coil)
TUV Certified
(EN61810)
Date code
10
Manufacturer
Lead Type
UL, CSA marking
6
-
8
JAPANSpecification
EA2-5NU
5
+
S: Coil polarity for Set
Certification Body
4
+
for Reset
Part numberR: Coil polarity
Manufacturer
EA2-5NU
Safety Standards and Ratings
Part number
3
File Number
R 9751153
Class
Rating
Basic insulation
Creepage and clearance
of coil to contact is more
than 2 mm
(According to EN60950)
Environmental Compliance
All KEMET relays are RoHS Compliant.
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
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Miniature Signal Relays – EC2/EE2 Series
Table 1 – Ratings & Part Number Reference
Part Number
Nominal Coil Voltage
(VDC)
Lead Type
Packaging
EC2-3(1)NU
EC2-4.5(1)NU
EC2-5(1)NU
EC2-12(1)NU
EC2-24(1)NU
EE2-3(1)NU
EE2-4.5(1)NU
EE2-5(1)NU
EE2-12(1)NU
EE2-24(1)NU
EE2-3(1)NU-L
EE2-4.5(1)NU-L
EE2-5(1)NU-L
EE2-12(1)NU-L
EE2-24(1)NU-L
EE2-3(1)NUH
EE2-4.5(1)NUH
EE2-5(1)NUH
EE2-12(1)NUH
EE2-24(1)NUH
EE2-3(1)NUH-L
EE2-4.5(1)NUH-L
EE2-5(1)NUH-L
EE2-12(1)NUH-L
EE2-24(1)NUH-L
EE2-3(1)NUX
EE2-4.5(1)NUX
EE2-5(1)NUX
EE2-12(1)NUX
EE2-24(1)NUX
EE2-3(1)NUX-L
EE2-4.5(1)NUX-L
EE2-5(1)NUX-L
EE2-12(1)NUX-L
EE2-24(1)NUX-L
EE2-3NKX1
EE2-4.5NKX1
EE2-12NKX1
EE2-3NKX-L1
EE2-4.5NKX-L1
EE2-12NKX-L1
3
4.5
5
12
24
3
4.5
5
12
24
3
4.5
5
12
24
3
4.5
5
12
24
3
4.5
5
12
24
3
4.5
5
12
24
3
4.5
5
12
24
3
4.5
12
3
4.5
12
Radial
Radial
Radial
Radial
Radial
Surface mount
Surface mount
Surface mount
Surface mount
Surface mount
Surface mount
Surface mount
Surface mount
Surface mount
Surface mount
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, Minimum footprint
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High solder joint reliability
Surface mount, High breakdown voltage, High solder joint reliability
Surface mount, High breakdown voltage, High solder joint reliability
Surface mount, High breakdown voltage, High solder joint reliability
Surface mount, High breakdown voltage, High solder joint reliability
Surface mount, High breakdown voltage, High solder joint reliability
Surface mount, High breakdown voltage, High solder joint reliability
Tube
Tube
Tube
Tube
Tube
Tube
Tube
Tube
Tube
Tube
Tape on Reel
Tape on Reel
Tape on Reel
Tape on Reel
Tape on Reel
Tube
Tube
Tube
Tube
Tube
Tape on Reel
Tape on Reel
Tape on Reel
Tape on Reel
Tape on Reel
Tube
Tube
Tube
Tube
Tube
Tape on Reel
Tape on Reel
Tape on Reel
Tape on Reel
Tape on Reel
Tube
Tube
Tube
Tape on Reel
Tape on Reel
Tape on Reel
(1) To complete KEMET part number, leave blank for Non-latch, insert S for Single coil, or T for Double coil. Designates latch type.
1
NKX type only available as Non-latch. Non-standard part, please contact KEMET to special order.
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
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Miniature Signal Relays – EC2/EE2 Series
Land Pattern – Millimeters
EC2 Series (bottom view)
Non-latch type and single coil latch type
1.05
1.05
Double coil latch type
2.54 2.54
1.05 5.08 5.08
2.54 2.54 8 - ø 0.88 - ø 0.8
1.055.08
5.08 2.542.54 2.548 - ø 0.8 8 - ø 0.8
2.54
V
V
1.11
1.11
V
1.05
1.05
V
1.05
1.11
1.11
X
X
X
X
1.11
1.11
0.5
0.5
1.05
1.05
V
V
X
X
X
V
X
EC2
EE2 (NU)
EE2 (NUH)
EE2 (NUX, NKX)
5.08
7.29
6.29
7.02
—
3.0
2.0
2.73
B Maximum
B Maximum
B
Maximum
B Maximum
X
1.11
K
P1 P1P1 P1
5.08 5.08
P1 P1 P1
5.08 P5.08
1
1.11
1.11
V
V
1.11
1.11
B Maximum
B Maxi
B Maximu
B Maximum
D Maximum
D Maximum
D
Maximum
D Maximum
H Maximum
H Maximum
H Maximum
H Maximum
K 0.25 0.25
K0.25 0.25
P2 P2
P2
P2
V
V
1.11
K
V
2.54
2.54 2.54
5.08 2.54
2.54
1.05 5.08 2.54
5.082.542.54
1.055.08 2.54
2.54 2.54 2.54
V
Series
0.5
0.5
V
Double coil latch type
1.11
1.11
D Maximum
D Maximum
D Maximum
D Maximum
1.11
1.11
1.05 5.08 2.54
5.08 2.54
2.54 2.54
1.055.08 2.54
5.082.54 2.54 2.54
V
V
V
EE2 Series (top view)
Non-latch type and single coil latch type
1.05
2.54 2.54 8 - ø 0.88 - ø 0.8
1.05 5.08 2.54
5.08 2.54
2.542.54
8 - ø 0.8 8 - ø 0.8
1.055.08 2.54
5.082.542.54
2.542.54 2.54
H Maximum
H Maximum
H Maximum
H Maximum
0.5
0.5
0.5
0.5
K
5.08 5.08
P1 P1 PP1 1 P1 P1
5.08 P5.08
P1 P1 P1 P1
1
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
K
K 0.25 0.25
K 0.25 0.25
R7002_EC2_EE2 • 2/27/2014
P2
P2
5
P2
P
Miniature Signal Relays – EC2/EE2 Series
Soldering Process
EC2 – Through-hole Mounting
Automatic Soldering
Preheating: 110–120°C / 110 seconds (maximum)
Solder temperature: 260°C maximum
Solder time: 5 seconds maximum
Note: KEMET recommends cooling down a printed circuit board to less than 110°C within 40 seconds after soldering.
Manual Soldering
Solder temperature: 350°C maximum
Solder time: 3 seconds maximum
EE2 – Surface Mounting
IRS Method
Temperature
(˚C)
Maximum 240˚C
220
200
180
45 (Maximum 70)
Time (seconds)
70 (Maximum 120)
190 (Maximum 300)
Note:
Temperature profile shows printed circuit board surface temperature on the relay terminal portion.
Please consult KEMET if you wish to use a temperature profile other than above.
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
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Miniature Signal Relays – EC2/EE2 Series
Contact Specifications
Item
Contact Form
2 Form C
Contact Material
Contact Ratings
EC2/EE2
Silver alloy with gold alloy overlay
Maximum Switching Power
60 W, 125 VA
Maximum Switching Voltage
220 VDC, 250 VAC
Maximum Switching Current
2A
Maximum Carrying Current
2A
Minimum Contact Ratings
10 mVDC, 10 µA*1
Initial Contact Resistance
75 mΩ maximum (initial)
Operating Time (excluding bounce)
Approximately 2 milliseconds
Release Time (excluding bounce)
Approximately 1 millisecond
Insulation Resistance
1,000 MΩ @ 500 VDC
NU, NUH, NUX:
1,000 VAC (for one minute), 1,500 V surge (10 x 160 µs)*2
Withstand Voltage
Between Open Contacts
NKX:
Make contact: 1,500 VAC (for one minute), 2,500 V surge (2 x 10 µs)*3
Break contact: 1,000 VAC (for one minute), 1,500 V surge (10 x 160 µs)*2
Between Adjacent Contacts
1,000 VAC (for one minute), 1,500 V surge (10 x 160 µs)*2
Between Coil and Contacts
Non-latch and single coil latch type:
1,500 VAC (for one minute), 2,500 V surge (2 x 10 µs)*3
Double coil latch type:
1,000 VAC (for one minute), 1,500 V surge (10 x 160 µs)*2
Shock Resistance
735 m/s2 (75 G) – misoperation
980 m/s2 (100 G) – destructive failure
Vibration Resistance
10 to 55 Hz, double amplitude 3 mm (20 G) – misoperation
10 to 55 Hz, double amplitude 5 mm (30 G) – destructive failure
Ambient Temperature
-40 to +85°C
Coil Temperature Rise
18°C at nominal coil voltage (140 mW)
Non-load
1 x 108 operations (Non-latch type)*4
1 x 107 operations (Latch type)
Load
50 VDC 0.1 A (resistive), 1 x 10 6 operations @ 85°C, 5 Hz
10 VDC 10 mA (resistive), 1 x 10 6 operations @ 85°C, 2 Hz
Running Specifications
Weight
Approximately 1.9 g
This value is a reference value in the resistance load. Minimum capacity changes depending on the switching frequency, environment temperature, and load.
Rise time: 10 µs; decay time to half crest: 160 µs.
*3
Rise time: 2 µs; decay time to half crest: 10 µs.
*4
This shows the number of operations with fatal defects. Stable characteristics are maintained for 1 x 107 operations.
*1
*2
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
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Miniature Signal Relays – EC2/EE2 Series
Coil Specifications
Non-latch Type (@ 20°C)
1
Nominal Coil Voltage
(VDC)
Coil Resistance
(Ω) ±10%
Operating Voltage1
(VDC)
3
64.3
2.25
0.3
140
4.5
145
3.38
0.45
140
140
Release Voltage1
(VDC)
Nominal Operating
Power (mW)
5
178
3.75
0.5
12
1028
9.0
1.2
140
24
2880
18.0
2.4
200
Reset Voltage1
(VDC)
Nominal Operating
Power (mW)
Test by pulse voltage.
Single Coil Latch Type (@ 20°C)2
Nominal Coil Voltage
(VDC)
1
2
Coil Resistance
(Ω) ±10%
Set Voltage1
(VDC)
3
90
2.25
2.25
100
4.5
202.5
3.38
3.38
100
5
250
3.75
3.75
100
12
1440
9.0
9.0
100
24
3840
18.0
18.0
150
Test by pulse voltage.
Latch type relays should be initialized to a known position before using. Only the specified polarity should be used to energize the coil.
Double Coil Latch Type (@ 20°C)2,3
Nominal Coil Voltage
(VDC)
3
4.5
5
12
24
Coil Resistance
(Ω) ±10%
Set Voltage4
(VDC)
Release Voltage4
(VDC)
S
64.3
2.25
–
R
64.3
–
2.25
S
145
3.38
–
R
145
–
3.38
S
178
3.75
–
R
178
–
3.75
S
1028
9.0
–
R
1028
–
9.0
S
2880
18.0
–
R
2880
–
18.0
Nominal Operating
Power (mW)
140
140
140
140
200
Latch type relays should be initialized to a known position before using. Only the specified polarity should be used to energize the coil.
Can not be driven by reverse polarity for reverse operation.
4
S = Set coil [pin #1 (+), pin #12 (-)], R = Reset coil [pin #6 (+), pin #7 (-)].
2
3
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
8
Miniature Signal Relays – EC2/EE2 Series
Coil Specifications cont’d
Non-latch, High Breakdown Voltage (NKX) Type (@ 20°C)
Nominal Coil Voltage
(VDC)
1
Coil Resistance
(Ω) ±10%
Operating Voltage1
(VDC)
Release Voltage1
(VDC)
Nominal Operating
Power (mW)
3
39.1
2.25
0.3
230
4.5
88.0
3.38
0.45
230
12
626.0
9.0
1.2
230
Test by pulse voltage.
Recommended Relay Drive Conditions
Coil Type
Rating
Non-latch
Ambient Temperature
Voltage: ≤ ±5% of nominal voltage
Square pulse (rise and fall time is rapid)
Pulse height: ≤ ±5% of nominal voltage
Pulse Width: > 10 ms
Single Coil
Double Coil
-40 to +85°C
Marking
Top view
Direction mark
(pin No. 1 and 12)
Part number
UL, CSA marking
E C 2-5N U
JAPAN
Manufacturer
Country of origin
0 50 1F
Date code
Direction mark
(pin No. 1 and 12)
Part number
Manufacturer
TUV, UL, CSA marking
E C 2-5N D
JAPAN
Country of origin
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
0 50 1F
Date code
R7002_EC2_EE2 • 2/27/2014
9
ES
ES
ES
EC2/EE2
SERIES
EC2/EE2
SERIES
EC2/EE2
EC2/EE2
SERIES
SERIES
EC2/EE2
EC2/EE2
SERIES
SERIES
Miniature Signal Relays – EC2/EE2 Series
PERFORMANCE
DATA
PERFORMANCE
Performance
Data DATA
PERFORMANCE
PERFORMANCE
DATA DATA
PERFORMANCE
PERFORMANCE
DATA DATA
□ COIL TEMPERATURE
RISE
□ COIL TEMPERATURE
RISE
□ COIL TEMPERATURE
RISE
□ Temperature
COIL TEMPERATURE
RISE
Coil Temperature
Rise
is measured
by coil resistance
Temperature
is measured
by coil RISE
resistance
□ COIL
TEMPERATURE
□Temperature
COIL
TEMPERATURE
Temperature
is measured
isRISE
measured
by coil resistance
by coil resistance
TemperatureTemperature
is measured
by coil resistance
Temperature
is measured
is by
measured
coil resistance
by coil resistance
Coil temperature
Coil temperature
Coil temperature
Coil temperature
60
60
rise (℃)
rise
(℃) Coil
60
60
Coil
temperature
rise (℃) rise temperature
(℃)
60
60
rise (℃)
rise (℃)
40
40
40
20
20
20
0
0
0
0
0
0
Coil temperature
Coil temperature
Coil temperature
Coil temperature
risetemperature
(℃)
rise
(℃) Coil
Coil
temperature
rise (℃) rise
30
30(℃)
30(℃)
30
rise (℃)
rise
40
40
40
20
20
20
0
0
0
100
200
300
200
300
0 100
100
0
100200
200
300
300
100
0 Applied
100
200
300
200
300
Applied
power (mW)
power
(mW)
Applied power
Applied
(mW)
power (mW)
Applied power
Applied
(mW)
power (mW)
30
20
20
20
10
10
10
0
0 0
0 0
0
Applied
Applied power
0.2Wpower 0.2W
Applied power
Applied
0.2W
power 0.2W
Applied power
Applied
0.2W power 0.2W
Applied
power 0.14W
Applied power
0.14W
Applied power
Applied
0.14W
power 0.14W
Applied
power
Applied
0.14W
power
0.14W
0.1W
Applied power 0.1W
Applied power
Applied
0.1W
power 0.1W
Applied power
Applied
0.1W power 0.1W
30
20
20
20
10
10
10
0
0 50
10
20
105
15
2015
0 50
105
15
10
20
15
20
5 0 Applied
10 5 time
15
10 time
20 15
Applied
(minute)20
(minute)
Applied time
Applied
(minute)
time (minute)
Applied time
Applied
(minute)
time (minute)
□ MAXIMUM
COIL VOLTAGE
□ MAXIMUM
COIL VOLTAGE
□ MAXIMUM
□This
MAXIMUM
COIL
VOLTAGE
COILvalue
VOLTAGE
is avalue
maximum
of permissible
This
is a maximum
ofCOIL
permissible
alteration. alteration.
□
MAXIMUM
□
MAXIMUM
COIL
VOLTAGE
VOLTAGE
Maximum
Coil
Voltage
This is a maximum
This is
a value
maximum
of permissible
value
of permissible
alteration. alteration.
□ SWITCHING
□ SWITCHING
CAPACITYCAPACITY
□ SWITCHING
□These
SWITCHING
CAPACITY
CAPACITY
arevalue.
maximum
value.
These
are □
maximum
□
SWITCHING
SWITCHING
CAPACITY
CAPACITY
Capacity
These are These
maximum
are value.
maximum
value.
Switching
Inquire
with
NEC
TOKIN
under continuous
use.
withis
NEC
TOKIN
under
continuous
use.alteration.
Inquire
with
NEC
TOKIN
for values
maximum
values
under continuous This isInquire
Inquireare
with
NEC TOKIN
for maximum
under
continuous
a maximum
This
value
a maximum
of permissible
value
ofalteration.
permissible
These
maximum
These
are
value.
maximum
value.
Inquire
withInquire
TOKIN
with NEC
under
TOKIN
continuous
under continuous
use.
use.
Inquire with
Inquire
NEC TOKIN
with NEC
for TOKIN
maximum
for maximum
values under
values
continuous
under continuous
Maximum
value
ofNEC
permissible
alteration
Maximum Values
Inquire with NEC
Inquire
TOKIN
with NEC
underTOKIN
continuous
underuse.
continuous use.
Inquire with Inquire
NEC TOKIN
with NEC
for maximum
TOKIN forvalues
maximum
undervalues
continuous
under continuous
2.0
2.0
2.0
1.0
1.0
Contact
Contact
Contact Contact
1.0
current (A)
current (A) Contact
Contact
0.5 (A)
current (A)current
0.5 (A)
current (A) current
0.5
0.2
0.2
0.2
0.1
0.1
0.1 10
10
10
2.0
2.0
200
200
200
200
2.0
200
200
1.0
Ratio of Ratio
1.0
150 ofof 150
Ratio of Ratio
150
150
1.0
nominalof
nominal
Ratio
of Ratio
150
nominal 150
nominal
0.5
coil
coil
nominal
nominal
0.5
100
100
coil
coil
100
100
0.5
voltage
voltage
coil
coil
100
100
voltage
voltage
0.2
(%)
(%)
DC(Resistive)
voltage
voltage
0.2 DC(Resistive)
50
50
(%)
(%)
DC(Resistive)
DC(Resistive)
50
50
0.2DC(Resistive)
AC(Resistive)
AC(Resistive)
(%)
(%)
DC(Resistive)
50
50
AC(Resistive)
0.1 AC(Resistive)
0.1 AC(Resistive)AC(Resistive)
10
20
50
100
-40
20
50
100
-40
-20
0 -2020 0 40 20 60 40 80 60100 80
0.110
250VAC 250VAC -40 -20 -400 -2020 0 4020 6040 80 6010080
20
20
50
50
100
100
250VAC 250VAC -40 -20 -40
20
10
50
20
100
50
100
0
-20
20 temperature
0 40 20temperature
60(℃40
100
Ambient
(℃ ) 80
Ambient
)80 60
Contact
Contact voltage
(V)voltage (V) 250VAC
220VDC
220VDC 250VAC
Ambient temperature
Ambient temperature
(℃ )
(℃ )
Contact voltage
Contact(V)
voltage (V)
220VDC
220VDC
Ambient temperature
Ambient temperature
(℃ )
(℃ )
Contact voltage
Contact
(V) voltage (V) 220VDC
220VDC
Applied Voltage
vs. Timing
□ APPLIED
VS. TIMING
(Sample:EE2-5NU)
□ APPLIED
VOLTAGEVOLTAGE
VS. TIMING
(Sample:EE2-5NU)
□ APPLIED
□ APPLIED
VOLTAGEVOLTAGE
VS. TIMING
VS. TIMING
(Sample:EE2-5NU)
(Sample:EE2-5NU)
(Sample: EE2-5NU)
□ APPLIED□VOLTAGE
APPLIED VS.
VOLTAGE
TIMINGVS. TIMING
(Sample:EE2-5NU)
(Sample:EE2-5NU)
4
4
4
3
3
3
Operate Operate
2
Operate Operate
2
time
time
Operate
Operate
time
time
2
(ms)
(ms)
time
time
1
(ms)
(ms)
1
(ms)
(ms)
1
0
0
0
0
0
0
4
4
4
3
3
3
2
2
2
1
1
1
0
0 1000
0
0100
100 0
4
4
4
3
3
Release 3 Release
2
Release Release
time
time
2
Release
Release
time
time
2
(ms)
(ms)
time
time
1
(ms)
(ms)
1
(ms)
(ms)
1
100
150
200
250
150
200
250
100
150
200
150
250
200
250
150
100 power
200
150
250
200
Applied
power
(mW) 250
Applied
(mW)
Applied power
Applied
(mW)
power (mW)
Applied power
Applied
(mW)
power (mW)
0
0
0
0
0
0
100
100
100
(Without coil(Without
diode) coil diode)
4 (Without coil
(Without
diode) coil diode)
4 (Without coil (Without
diode) coil diode)
4
3
3
3
2
2
2
1
1
1
0
0 1000
100
200
300
400
200
300
400
0
100
200
300
200
400
300
400
0100
100 0 Applied
200
100 power
300
200
400
300
Applied
power
(mW) 400
(mW)
Applied power
Applied
(mW)
power (mW)
Applied power
Applied
(mW)
power (mW)
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
11
11
11
11
11
11
R7002_EC2_EE2 • 2/27/2014
●All specifications
in and
this production
catalog andstatus
production
statusare
of products
subject
to change
without
Prior to the
purchase,
please
TOKINproduct
for updated
●All specifications
in this catalog
of products
subject toare
change
without
notice.
Prior notice.
to the purchase,
please
contact
NECcontact
TOKIN NEC
for updated
data.product data.
10
Miniature Signal Relays – EC2/EE2 Series
EA2/EBE2 SERIES
EA2/EBE2 SERIES
EA2/EBE2 SERIES
Performance Data cont’d
Operate
and Release
Voltage vs. Ambient Temperature
� OPERATE
AND RELEASE VOLTAGE VS.AMBIENT TEMPERATURE
� This
OPERATE
AND
RELEASE
VOLTAGE
VS.AMBIENT
TEMPERATURE
a typical
change
operate (release)
voltage.
The value
is estimated,
voltage must so
be applied
This shows
ashows
typical
change
ofofoperate
(release)
voltage.
Theof must
valueoperate
of must
operatesoiscoilestimated,
coil voltage must be applied higher
This shows a typical change of operate (release) voltage. The value of must operate is estimated, so coil voltage must be applied
more
than this value
for
safety operation.
For hot
start operation,
please inquire with NEC TOKIN.
�
OPERATE
AND
RELEASE
VOLTAGE
VS.AMBIENT
TEMPERATURE
than this value
for this
safe
operation.
For hot For
start
please
inquirewithwith
more than
value
for safety operation.
hotoperation,
start operation,
please inquire
NECKEMET.
TOKIN.
This shows a typical change of operate (release) voltage. The value of must operate is estimated, so coil voltage must be applied
more than this value for safety operation. For hot start operation, please inquire with NEC TOKIN.
100
100
Must operate voltage
Must operate voltage
80
100
80
Ratio of nominal
Ratio of nominal 60
80
coil voltage (%)
60
coil voltage (%)
Ratio of nominal
Operate voltage (typical)
Operate voltage (typical)
Must operate voltage
Operate voltage (typical)
4060
40
coil voltage (%)
Release voltage (typical)
Release voltage (typical)
2040
20
Release voltage (typical)
020 -40
0 -40
-20
-20
-40
-20
0
0
20
40
60
0
20
40
60
Ambient temperature (°C)
Ambient
temperature
(°C)
0
20
40
60
80
80
100
100
80
100
Running
Test (Non-load)
Ambient temperature (°C)
� RUNNING TEST (Non-load)
RUNNING 5
TEST
(Non-load)
(Load: �none;
VDC,
50 Hz, 50% duty; Ambient
Temperature:
room
temperature;
Sample: EE2-5NU,
(Load:Drive:
none, Drive:5VDC，50Hz，50%duty,
Ambient temperature
:room
temperature,
Sample:EA2-5NU
,20pieces) 20 pieces)
(Load: none, Drive:5VDC，50Hz，50%duty, Ambient temperature :room temperature, Sample:EA2-5NU ,20pieces)
10000 TEST (Non-load)
RUNNING
10000
(Load: none, Drive:5VDC，50Hz，50%duty, Ambient temperature :room temperature, Sample:EA2-5NU ,20pieces)
�
5
10000
1000
1000
Contact
Contact
resistance
resistance 1000
(mΩ)
Contact
(mΩ)
100
resistance 100
(mΩ)
100
10
10
0
10
�
0
0
20
50
100
20
50
100
4
Operations (×10 ) 4
20Operations
50 (×10
100)
500
500
500
RUNNING TEST(Load)
Operate 4
Operate
voltage 3
voltage
(V)Operate
(V)
2
Release
voltage
Release
voltage
1
(V)
voltage
(V)Release
(V)
0
1000 voltage
1000(V)
1000
5
Operate voltage
Operate voltage
4
5
Operate voltage
3
4
2
3
Release voltage
Release voltage
1
2
0
1
0
0
0
0
Release voltage
20
50
100
500
20
50
100
500
4
Operations (×10 ) 4
Operations
20
50
100 (×10 )
500
�
RUNNING TEST(Load)
4
(Load: 50VDC 0.1A resistive, Drive: 5VDC,5Hz,50%duty,Ambient
temperature:85 °C, Sample:EA2-5NU ,10pieces)
Operations (×10 )
1000
1000
1000
4
Operations
(×10 )
(Load: 50VDC 0.1A resistive, Drive: 5VDC,5Hz,50%duty,Ambient temperature:85 °C, Sample:EA2-5NU
,10pieces)
Running
(Load)
� Test
RUNNING
TEST(Load)
(Load:
50VDC
resistive,
Drive:55VDC,5Hz,50%duty,Ambient
temperature:85
°C, Sample:EA2-5NU
,10pieces)
5Temperature:
10000
(Load: 50 VDC, 0.1
A0.1A
resistive;
Drive:
VDC, 5 Hz, 50% duty; Ambient
85°C; Sample:
EE2-5NU, 10 pieces)
5
10000
4
10000
1000
1000
Contact
Contact
resistance
resistance
(mΩ)
Contact
1000
(mΩ)
resistance 100
100
(mΩ)
100
10
10
10
0
Operate 3
Operate
voltage
voltage 2
(V)Operate
(V)
Release
voltage 1
Release
(V)
0
Release
0
2
2
5
5
10
10
50
50
100
100
50
100
4
0
Operations (×10 ) 4
(×10
2 Operations
5
10 )
Operate voltage
Operate voltage
4
5
3
4
Operate voltage
2
3
Release voltage
Release voltage
1
2
Release voltage
0
1
0
0
0
2
0
2
2
5
10
5
10
4
Operations (×10 ) 4
)
Operations
(×10
5
10
50
100
50
100
50
100
4
Operations (×10 )
4
Operations (×10 )
9
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
9
9
R7002_EC2_EE2
• 2/27/2014
11
S
SRIES
0
Miniature Signal Relays – EC2/EE2 Series
EC2/EE2 SERIES
EC2/EE2
SERIES
EC2/EE2
SERIES
Performance Data cont’d
□ BREAKDOWN VOLTAGE
Sample: EC2-5NU 10peices
□ BREAKDOWN
VOLTAGE
□ BREAKDOWN
VOLTAGE
Breakdown Voltage
(Sample: EE2-5NU, 10 pieces)
EC2-5NU
Sample:Sample:
EC2-5NU
10peices10peices
(a) Between open contacts
(b) Between adjacent contacts
(a) Between open contacts
100 (a) Between open contacts
100
50
100
50
Distribution
Distribution
50
Distribution
(b) Between
adjacentadjacent
contactscontacts
100 (b) Between
100
50
100
Distribution (%)
50
50
Distribution
(%)
Distribution
(%)
0
0.5
1.0
1.5
2.0
1.0
1.5
2.0
2.5
0 Breakdown voltage (K V)
0
0
Breakdown
0.5
1.0
1.5
2.0
1.0 voltage
1.5
2.5
0.5
1.0
1.5
2.0
1.0
1.5
2.0 (K V)2.0
2.5
Breakdown
voltage
Breakdown
voltage
Breakdown
voltage (K
V) (K V)
Breakdown
voltage (K
V) (K V)
(C) Between coil and contact
0
0
(C) Between
and contact
coil and coil
contact
100 (C) Between
100
100
50
Distribution (%)
50
Distribution
(%)
Distribution
(%) 50
0
0.5
1.5
2.0
2.5
0
0.5 voltage
1.5
2.0
0.5
1.5
2.0(K V)2.5
Breakdown
0
2.5
Breakdown
voltage
Breakdown
voltage (K
V) (K V)
Alteration of Voltage
in DenseOFMounting
□ ALTERNATION
VOLTAGE IN DENSE MOUNTING (Magnetic interference)
□
ALTERNATION
OF VOLTAGE
IN DENSE
MOUNTING
(Magnetic
interference)
(magnetic interference)
□ ALTERNATION
OF VOLTAGE
IN DENSE
MOUNTING
(Magnetic
interference)
Alternation of operate voltage
+40
1000
Ratio of
Alternation of operate voltage
Alternation
of operate
Alternation
of operate
voltage voltage
+30
+40
+20
+30
+40
+10
+20
0
+10
+20
+40
+40
+10
+20
Ratio of
0
+10
alternation
(%) of-10 0
Ratio of Ratio
+20
+30
+10
alternation
(%) of-10 0
0
Ratio of Ratio
alternation
alternation
(%) -20
-10(%) -10
-30
-20
-20
-40
-30
a
-40
-30
-40
a
b
c
a
b
d
e
b
c
c
d
layout
Mounting
+30
+10
0
alternation
alternation
(%) -20
-10(%) -10
-30
-20
-20
-40
-30
-30
a -40 b
-40
f
a
a
b
f
d
e
Alternation
of operate
Alternation
of operate
voltage voltage
+30
+40
+20
+30
e f
ON
ON
Devicetest
under test
Device under
OFF
OFF
ON
OFFOFF
ON ON
ONOFF
OFF
ON
OFF
a
a
ON
ON
ON
ON
ON
ON
ON
e
b
ef
f
mm
2.54
2.54
mm
mm
2.54mm
2.54mm2.54mm
d
c
c
d
d
2.54
mm
2.54
2.54
mm
mm
OFF
ON
ONe
c
b
f
de
OFF
ON OFF
ON
b
e
OFF
ON
100
a
2.54
OFF
ON OFF
ON
d
Mounting
Mounting
layout layout
Mounting
layout layout
Mounting
Device under test
c
b
c
c
d
Mounting
layout
OFF
OFF
OFF
OFF
OFF
OFF
OFF f
e
OFF
f
f
13
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
13
13
R7002_EC2_EE2 • 2/27/2014
●All specifications in this catalog and production status of products are subject to change without notice. Prior to the purchase, please contact NEC TOKIN for updated product data.
12
S
Miniature Signal Relays – EC2/EE2 Series
Tube Packing – Millimeters
35 pieces / Tube (anti-static)
15.5
543
11.9
Direction of relay direction mark
Rubber stopper (Red)
Rubber stopper (Green)
Tape & Reel Packaging Information (EE2 only) – Millimeters
Appearance
Reel
Reel
Reel
pieces
/ Reel
500 500
pieces
/ Reel
500diameter:
pieces
/380mm
Reel
ReelReel
diameter:
380mm
Reel diameter: 380mm
Emboss
Emboss
Emboss
Carrying
Carrying
tapetape
Carrying tape
cover
TopTop
cover
tapetape
Top cover tape
Tape Dimensions
8.1
max.max.
A8.1 A
1.751.75
2.0 2.0
Φ 1.5
Φ 1.5
Φ 2.2
Φ 2.2
Φ 1.5
16 16
4
2.0
16
4
4
Φ 2.2
0.4 0.4
1.75
max.A8.1
0.4
11.511.5
14.7
15.514.7
15.5
24.024.0
11.5
12.1
B 12.1
B
24.0
Series
A
B
NU-L, NUX-L,
NKX-L
Maximum 10.9
10.0
NUH-L
Maximum 11.1
8.0
14.7
15.5
12.1
B
K AND
TAPE
CARRYING
DIRECTION
Relay
Direction
Mark and Tape Carrying Direction
ARK
AND
TAPE
CARRYING
DIRECTION
Sprocket
holehole
Sprocket
Direction
markmark
Direction
ND TAPE CARRYING DIRECTION
Sprocket hole
Direction mark
Direction of unreeling
Direction of unreeling
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
13
NOTE ON CORRECT USE
1. Notes on contact load
at a temperature outside this range may adversely affect
Make sure that the contact load is within the specified range;
otherwise,
lifetime Series
of the
Miniature Signal
Relays –the
EC2/EE2
contacts will be shortened
insulation or contact performance.
- If the relay is used for a long period of time in highly humid
considerably.
(RH 85% or higher) environment, moisture may be absorbed
Note that the running performance shown is an example,
into the relay. This moisture may react with the NOx and
that it Relays
varies depending on parameters such as the
Notes onandUsing
type of load, switching
frequency, driver circuit, and
ambient temperature under the actual
operating conditions.
1. Contact Load
Evaluate the performance by using the actual
circuit before
SOx generated by glow discharges that occur when the
contacts are opened or closed, producing nitric or sulfuric
acid. If this happens, the acid produced may corrode the
metallic parts of the relay, causing operational malfunction.
- If any material containing silicon (silicon rubber, silicon oil,
using the relay.
Make sure
that the contact load is within the specified range;
otherwise, the lifetime of the contacts will be shortened considerably.
2. Driving relays
and silicon based coating material) is used in the
- If the
the internal
connection
diagram of
a relay is
shows
+ and neighborhood
of relay,
there is some
that these
Note that
running
performance
shown
an example,
and
that it varies
depending
onpossibility
parameters
such as the type of load,
symbols on the coil, apply the rated voltage to the relay in
materials will emit silicon gas that will penetrate the relay. In
switching frequency, driver circuit, and ambient temperature under the actual operating conditions.
the specified
direction. If a rippled DC current source is
used, abnormalities such
as beat at the coil may occur.
- The maximum voltage that can be applied to the coil of the
2. Driving Relays
relay
varies depending on the ambient temperature.
this case, the switching contact may generate silicon
compounds on the surface of contacts. This silicon
compound may result in contact failure. Avoid use of relay in
such an environment.
• If the Generally,
internal connection
of a relay
symbolsthe
on the
coil, apply
the rated
the higher thediagram
voltage applied
to theshows
coil, the+ and- - Because
operating
temperature
rangevoltage
varies to the relay in the
shorter
the
operating
time.
Note,
however,
that
a
high
depending
on
the
humidity,
use
the
relay
in
the
temperature
specified direction. If a rippled DC current source is used, abnormalities such as heat at the coil may occur.
voltage also increases the bounce of the
contacts and
range illustrated in the figure below. Prevent the relay from
• The maximum
that closing
can befrequency,
applied which
to themay
coil of the
depending
onofthe
ambient temperature. Generally, the
the contact voltage
opening and
beingrelay
frozenvaries
and avoid
the generation
condensation.
shorten
the
lifetime
of
the
contacts.
higher the voltage applied to the coil, the shorter the operating time. Note, however, that high voltage also increases the bounce
- If the driving voltage waveform of the relay coil rises and
85
of thefalls
contacts
the contact
opening
gradually,and
the inherent
performance
of theand
relayclosing
may not frequency,80which may shorten the lifetime of the contacts.
be fully realized. Make sure that the voltage waveform
• For consistent
operation, the driving voltage should have rise and
60 fall times of less than 1 ms.
instantaneously rises and falls as a pulse.
Humidity
(%RH) 40
Nominal
coil voltage
20
5
-60 -40 -20 0 20 40
0
60
80 100
Temperature (°C )
<1msec.
<1msec.
- The relay maintains constant sealability under normal
atmospheric pressure (810 to 1,200 hpa). Its sealability may
• For a latching relay, apply a voltage to the coil accordingbetodegraded
the polarity
the internal
connection diagram of the relay.
or the specified
relay may beindeformed
and malfunction
if it is used under barometric conditions exceeding the
- For a latching relay, apply a voltage to the coil according to
• If a current
is applied to the coil over a long period of time,
the coil temperature rises, promoting generation of organic gas inside
specified range.
the polarity specified in the internal connection diagram of
the relay,
which
may
result
in
faulty
contacts.
In
this
case,
use
of aapplies
latching
is recommended.
- The same
whenrelay
the relay
is stored or transported.
the relay.
- If a current is applied to the coil over a long period of time,
Keep the upper-limit value of the temperature to which the
applied to or
faulty operations may result.
• The operating
time and release time indicate the time required
for each contact to close after the voltage has been applied to or
relay is exposed after it is removed from the carton box to
the coil temperature rises, promoting generation of organic
removed
from
the
coil.
However,
because
the
relay
has
a
mechanical
structure, a bounce state exists at the end of the operating
within 50°C.
gas inside the relay, which may result in faulty contacts. In
Permanent
magnets
are used
in polarized
relays.after
For this
this
case,
use
of
a
latching
relay
is
recommended.
and release times. Furthermore, because additional time is required until the
contact
stabilizes
being in a high-resistance
reason, when magnets, transformers, or speakers are
- The operating time and release time indicate the time
state,required
care must
be
taken
when
using
the
relay
at
high
speeds.
located nearby the relay characteristics may change and
for each contact to close after the voltage has been
removed from the coil. However, because the
relay has a mechanical structure, a bounce state exists at
3. Operating
Environment
the end of the operating and release times. Furthermore,
- If excessive vibration or shock is applied to the relay, it may
malfunction and the contacts remain closed. Vibration or
shock
the specified
relay duringtemperature
operation mayrange.
cause Use of a relay at a
additional
timemounted
is required
untilapplication
the contact set is
• Makebecause
sure that
the relay
in the
usedapplied
withinto the
considerable damage to or wearing of the contacts. Note that
stabilizes after being in a high-resistance state, care must be
temperature
outside this range may adversely affect insulation
or contact performance.
operation of a snap switch mounted close to the relay or
taken when using the relay at high speeds.
shock
due85%
to theor
operation
magnetic solenoid
may alsomay be absorbed into the
Operating
environment
• If the 3.relay
is used
for a long period of time in highly humid
(RH
higher)ofenvironment,
moisture
- Make sure that the relay mounted in the application set is
cause malfunctioning.
relay.used
Thiswithin
moisture
may react with the NOx and SOx generated by glow discharges that occur when the contacts are opened or
the specified temperature range. Use of a relay
closed, producing nitric or sulfuric acid. If this happens, the acid produced may corrode the metallic parts of the relay, causing
operational malfunction.
13
• If any material containing silicon (silicon rubber, silicon oil, and silicon based coating material) is used in the neighborhood of
relay, there is some possibility that these materials will emit silicon gas that will penetrate the relay. In this case, the switching
contact may generate silicon compounds on the surface of contacts. This silicon compound may result in contact failure. Avoid
use of relay in such an environment.
●All specifications in this catalog and production status of products are subject to change without notice. Prior to the purchase, please contact NEC TOKIN for updated product data.
●Please request for a specification sheet for detailed product data prior to the purchase.
●Before using the product in this catalog, please read "Precautions" and other safety precautions listed in the printed version catalog.
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
2007.08.03 P0886EMDD03VOL01E
R7002_EC2_EE2 • 2/27/2014
14
ng the actual
circuit before
metallic parts of the relay, causing operational malfunction.
- If any material containing silicon (silicon rubber, silicon oil,
and silicon based coating material) is used in the
am of a relay shows + and -
neighborhood of relay, there is some possibility that these
rated voltage to the relay in
materials will emit silicon gas that will penetrate the relay. In
pled DC current source is
at at the coil Miniature
may occur.Signal
this case, the switching contact may generate silicon
Relays
– EC2/EE2
compounds
on Series
the surface
of contacts. This silicon
be applied to the coil of the
compound may result in contact failure. Avoid use of relay in
the ambient temperature.
such an environment.
Notes on Using
Relays
cont’dtemperature
- Because
the operating
ge applied to the coil, the
ote, however, that a high
nce of the
range
varies
depending on the humidity, use the relay in the temperature
• Because the
range
varies
depending
on the humidity, use the relay in the temperature range illustrated in
rangeoperating
illustrated intemperature
the figure below.
Prevent
the relay
from
frozen
and avoid
generation
condensation.
the figure being
below.
Prevent
thetherelay
fromofbeing
frozen and avoid the generation of condensation.
contacts and
ng frequency, which may
s.
m of the relay coil rises and
rmance of the relay may not
hat the voltage waveform
a pulse.
85
80
60
Humidity
(%RH) 40
20
5
-60 -40 -20 0 20 40
60
80 100
Temperature (°C )
<1msec.
• The
The relay constant
maintains constant
sealability
normal
relay -maintains
sealability
underunder
normal
atmospheric pressure (810 to 1,200 hpa). Its sealability may be degraded
atmospheric pressure (810 to 1,200 hpa). Its sealability may
or the relay may be deformed and malfunction if it is used under barometric conditions exceeding the specified range.
be degraded or the relay may be deformed and malfunction
it is used
underthe
barometric
the
• The sameif applies
when
relay is conditions
stored orexceeding
transported.
Keep the upper-limit value of the temperature to which the relay is
rnal connection diagram of
specified range.
exposed after
it is removed from the carton box to within 50°C.
- The same applies when the relay is stored or transported.
tage to the coil according to
the upper-limit
value in
of polarized
the temperature
to which
• PermanentKeep
magnets
are used
relays.
For the
this reason, when magnets, transformers, or speakers are located nearby
relay is exposed after it is removed from the carton box to
the
relay
characteristics
may
change
and
faulty
operations
may result.
result in faulty contacts. In
within 50°C.
l over a long period of time,
oting generation of organic
- Permanent magnets are used in polarized relays. For this
• If excessive
vibration or shock is applied to the relay, it may malfunction and the contacts remain closed. Vibration or shock
reason, when magnets, transformers, or speakers are
applied
to
the
relay
during
operation
may cause
considerable
damage to or wearing of the contacts. Note that operation of a
located
nearby
the relay
characteristics
may change
and
e after the voltage has been
faulty
operations
may
result.
coil. However, because
the
snap switch mounted close to the relay or shock due to the operation of magnetic solenoid may also cause malfunctioning.
s recommended.
ase time indicate the time
e, a bounce state exists at
- If excessive vibration or shock is applied to the relay, it may
elease times. Furthermore,
malfunction and the contacts remain closed. Vibration or
equired until the contact
shock applied to the relay during operation may cause
sistance state, care must be
considerable damage to or wearing of the contacts. Note that
4. Mounting
• When mounting
a relay onto a PC board using an automatic chip mounter, if excessive force is applied to the cover of the relay
operation of a snap switch mounted close to the relay or
when the shock
relay due
is chucked
or inserted,
thesolenoid
cover may
be damaged or the characteristics of the relay degraded. Keep the force
to the operation
of magnetic
may also
ted in the applicationapplied
set is
malfunctioning.
tocause
the relay
to within 1 kg.
h speeds.
ature range. Use of a relay
• Avoid bending the pins to temporarily secure the relay to the PC board. Bending the pins may degrade sealability or adversely
affect the internal mechanism.
13
• Ventilation immediately after soldering is recommended. Avoid immersing the relay in cleaning solvent immediately after
soldering due to the danger of thermal shock being applied to the relay.
• Use an alcohol-based or water-based cleaning solvent. Never use thinner and benzene because they may damage the relay
housing.
of products are subject to change without notice. Prior to the purchase, please contact NEC TOKIN for updated product data.
duct data prior to the purchase.
ecautions" and other safety precautions listed in the printed version catalog.
• Do not use ultrasonic cleaning because the vibration energy generated by the ultrasonic waves may cause the contacts to
remain closed.
5. Handling and Storage
2007.08.03 P0886EMDD03VOL01E
• Relays are packaged in magazine cases for shipment. If a space is created in the case after some relays have been removed, be
sure to insert a stopper to secure the remaining relays in the case. If relays are not well secured, vibration during transportation
may cause malfunctioning of the contacts.
• Exercise care in handling the relay so as to avoid dropping it or allowing it to fall. Do not use a relay that has been dropped. If a
relay drops from a workbench to the floor, a shock of 9,800 m/s2 (1,000 G) or more is applied to the relay, possibly damaging its
functions. Even if a light shock has been applied to the relay, thoroughly evaluate its operation before using it.
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
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Miniature Signal Relays – EC2/EE2 Series
Notes on Using Relays cont’d
• Latching relays are factory-set to reset state for shipment. A latching relay may be set, however, by vibration or shock applied
while being transported. Be sure to forcibly reset the relay before using it in the application set. Also note that the relay may be
set by unexpected vibration or shock when it is used in a portable set.
• The sealability of a surface mount (SMT) relay may be lost if the relay absorbs and is then heated during soldering. When storing
relays, therefore, observe the following points:
1.For standard packing, please use relays within 12 months after delivery (storage conditions: 30°C / 60% RH). If the relays
have moisture absorption, dehumidify as follows:
– Tape Packaging: 50 ±5°C, 200–300 hours.
– Simple Relay: 85 ±5°C, 48 hours.
2. For MBB packing, please use relays within 2 years after delivery (storage conditions: 30°C / 60% RH). After opening MBB
packing, please use within 3 months (storage conditions: 30°C / 60% RH).
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
16
Miniature Signal Relays – EC2/EE2 Series
KEMET Corporation
World Headquarters
Europe
Asia
Southern Europe
Paris, France
Tel: 33-1-4646-1006
Northeast Asia
Hong Kong
Tel: 852-2305-1168
Mailing Address:
P.O. Box 5928
Greenville, SC 29606
Sasso Marconi, Italy
Tel: 39-051-939111
Shenzhen, China
Tel: 86-755-2518-1306
www.kemet.com
Tel: 864-963-6300
Fax: 864-963-6521
Central Europe
Landsberg, Germany
Tel: 49-8191-3350800
Corporate Offices
Fort Lauderdale, FL
Tel: 954-766-2800
Kamen, Germany
Tel: 49-2307-438110
North America
Northern Europe
Bishop’s Stortford, United Kingdom
Tel: 44-1279-460122
2835 KEMET Way
Simpsonville, SC 29681
Southeast
Lake Mary, FL
Tel: 407-855-8886
Espoo, Finland
Tel: 358-9-5406-5000
Northeast
Wilmington, MA
Tel: 978-658-1663
Beijing, China
Tel: 86-10-5829-1711
Shanghai, China
Tel: 86-21-6447-0707
Taipei, Taiwan
Tel: 886-2-27528585
Southeast Asia
Singapore
Tel: 65-6586-1900
Penang, Malaysia
Tel: 60-4-6430200
Bangalore, India
Tel: 91-806-53-76817
Central
Novi, MI
Tel: 248-306-9353
West
Milpitas, CA
Tel: 408-433-9950
Mexico
Guadalajara, Jalisco
Tel: 52-33-3123-2141
Note: KEMET reserves the right to modify minor details of internal and external construction at any time in the interest of product improvement. KEMET does not
assume any responsibility for infringement that might result from the use of KEMET Capacitors in potential circuit designs. KEMET is a registered trademark of
KEMET Electronics Corporation.
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
17
Miniature Signal Relays – EC2/EE2 Series
Disclaimer
This product has been made available through a Private Label Agreement and a Development and Cross-Licensing Agreement between KEMET and NEC TOKIN to expand market
and product offerings for both companies and their respective customers. For more information, please visit http://www.kemet.com/nectokin.
Allproductspecifications,statements,informationanddata(collectively,the“Information”)inthisdatasheetaresubjecttochange.Thecustomerisresponsibleforcheckingand
verifying the extent to which the Information contained in this publication is applicable to an order at the time the order is placed.
All Information given herein is believed to be accurate and reliable, but it is presented without guarantee, warranty, or responsibility of any kind, expressed or implied.
StatementsofsuitabilityforcertainapplicationsarebasedonKEMETElectronicsCorporation’s(“KEMET”)knowledgeoftypicaloperatingconditionsforsuchapplications,butare
notintendedtoconstitute–andKEMETspecificallydisclaims–anywarrantyconcerningsuitabilityforaspecificcustomerapplicationoruse.TheInformationisintendedforuseonly
by customers who have the requisite experience and capability to determine the correct products for their application. Any technical advice inferred from this Information or otherwise
provided by KEMET with reference to the use of KEMET’s products is given gratis, and KEMET assumes no obligation or liability for the advice given or results obtained.
Although KEMET designs and manufactures its products to the most stringent quality and safety standards, given the current state of the art, isolated component failures may still
occur. Accordingly, customer applications which require a high degree of reliability or safety should employ suitable designs or other safeguards (such as installation of protective
circuitry or redundancies) in order to ensure that the failure of an electrical component does not result in a risk of personal injury or property damage.
Although all product–related warnings, cautions and notes must be observed, the customer should not assume that all safety measures are indicted or that other measures may not
be required.
© KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com
R7002_EC2_EE2 • 2/27/2014
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