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UL
CSA VDE
Pending Pending Pending
AQ-E
RELAYS
AQ-E SOLID STATE RELAY
FEATURES
28.0
1.102
5.0
.197
1. Conforms to European safety standards (VDE0110)
dielectric distance between input and output
15.0
.591
• Creepage distance: Min. 3.0 mm
• Clearances distance: Min. 2.5 mm
2. The small-sized slim type
28 mm (L)×5 mm (W)×15 mm
1.063 inch (L)×.197 inch (W)×.591 inch
permits high density mounting to PC
board
3. High dielectric strength: 2,500V AC
(between input and output)
4. Two load types available:
DC output type (3A)
AC output type (1A)
5. Zero-cross type are availale (AC
type)
The zero-cross type generates minimal
noise
6. Snubber circuit integrated (AC type)
The snubber circuit is integrated to prevent malfunction caused by the rapid rise
of voltage on the output side, such as inductive load and current.
mm inch
TYPES
Type
TYPICAL APPLICATIONS
Load voltage
AC output
75 to 250 V AC
DC output
3 to 60 V DC
Input voltage
5 V DC
12 V DC
24 V DC
5 V DC
12 V DC
24 V DC
Part No.
AQE12105
AQE12112
AQE12124
AQE34205
AQE34212
AQE34224
• Interface relays for programmable controllers
• Industrial equipment
• Timers and counters
• Air conditioners
ORDERING INFORMATION
Ex. AQE
1
2
1
0
5
Load current
Load voltage
Type
Input voltage
1: 1 A
3: 3 A
2: 75 to 250 V AC
4: 3 to 60 V DC
1: AC output (Zero-cross)
2: DC output
05: 5 V DC
12: 12 V DC
24: 24 V DC
(Note) Standard packing: Carton 20 pcs., Case 1,000 pcs.
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SPECIFICATIONS
Ratings (at 20°C 68°F, Input voltage ripple: 1% or less)
Type
Part No.
AQE12105
Input voltage
4 to 6 V DC
Item
Input Input impedance
side
Drop-out voltage, min.
Reverse voltage
Max. load current
Load voltage
Frequency
Non-repetitive
surge current
Max. "OFF-state"
Load
leakage current
side
Max. "ON-state"
voltage drop
Min. load curent
OFF state dV/dt
Max. operating
speed
Approx. 0.5k
Ω
AC output
AQE12112
9.6 to 14.4 V
DC
Approx. 1.3k
Ω
0.5 V DC
1.2 V DC
Approx. 3k Ω
Approx. 0.5k
Ω
DC output
AQE34212
9.6 to 14.4
V DC
Approx. 1.3k
Ω
2.4 V DC
0.5 V DC
1.2 V DC
AQE12124
21.6 to 26.4
V DC
AQE34205
4 to 6 V DC
AQE34224
21.6 to 26.4
V DC
Remarks
Approx. 3k Ω
2.4 V DC
3V
1 A AC
75 to 250 V AC
45 to 65 Hz
3 A DC
3 to 60 V DC
—
20 A
15 A
1.5 mA (applied 200 V)
10µA
1.6 V
0.3 V
20 mA
50 V/µs
1 mA
—
—
0.5cps.
AC: In one cycle at 60 Hz
DC: 10 ms
at Max. carrying current
at rated operating voltage,
rated load voltage and current
Characteristics (at 20°C 68°F, Input voltage ripple: 1% or less)
Item
Operate time max.
Release time, max.
Insulation resistance, min.
Breakdown voltage
Functional
Vibration
resistance Destructive
Functional
Shock
resistance Destructive
Ambient temperature
Storage temperature
Operational method
AC output
DC output
(1/2 cycle of voltage sine wave) + 1 ms
2 ms
(1/2 cycle of voltage sine wave) + 1 ms
0.4 ms
109 Ω between input and output
2,500 Vrms between input and output
10 to 55 Hz double amplitude of 1.5 mm
10 to 55 Hz double amplitude of 1.5 mm
Min. 490 m/s2 {50 G}
Min. 490 m/s2 {50 G}
–30°C to +80°C –22°F to +176°F
–30°C to +100°C –22°F to +212°F
Zero-cross (Turn-ON and Turn-OFF)
—
Remarks
Using 500 V DC megger
Initial for 1 min.
1 hour for X, Y, Z axes
10 min. for X, Y, Z axes
5 times each for X, Y, Z axes
4 times each for X, Y, Z axes
REFERENCE DATA
1. Load current vs. ambient temperature
2.-(1) Non-repetitive surge current vs. carrying
time (AC output)
2.-(2) Non-repetitive surge current vs. carrying
time (DC output)
20
2.5
DC type
2.0
1.5
AC type
1.0
Non-repetitive surge current, A
Load current, A
3.0
Non-repetitive surge current, A
3.5
30
20
10
15
10
5
0.5
0
–30
2
0
20
40
60
80
Ambient temperature, °C
0
1
2
3 4 5 7 10
20 30 4050 70 100
No. of cycles at 60 Hz
0
10
100
Carrying time, ms
1,000
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4.-(1) Load current vs. ambient temperature
characteristics for adjacent mounting
(AC output)
30
1.2
25
1.0
=15 mm
.591 inch
0.8
=10 mm
.394 inch
0.6
=5 mm
.197 inch
Load current, A
Input current, mA
3. Input voltage vs. input current characteristics
ª W
20
15
(5 V type)
(12 V type)
10
(24 V type)
5
4.-(2) Load current vs. ambient temperature
characteristics for adjacent mounting
(DC output)
3.5
0.4
3.0
Load current, A
aqe.fm
=15 mm
.591 inch
=10mm
.394 inch
=5mm
.197 inch
2.5
2.0
1.5
1.0
0.2
0.5
= Adjacent mounting pitch
= Adjacent mounting pitch
0
5
10
15
20
25
Input voltage, V
0
0
30
–20
0
20
40
60
80 100
Ambient temperature, °C
-20
0
20
40
60
80 100
Ambient temperature, °C
DIMENSIONS
mm inch
15.0 max.
0.5 .591 max.
.020
3.78
.149
0.5±0.1
.020±.004
1.2 .047
5.0
.197
2-1.0 ±0.1
2-.039 ±.004
+0.2
–0.1
+.008
–.004
2-0.5
2-.020
±0.3
5.04
.198
21.42
.843
±0.5
5.04 ±0.3 3.5±.020
.198 ±.012 .138
1.9
.075
±0.3
21.42±.012
.843
28.0 max.
1.102 max.
3.78±.012
.149
2-1
2-. .6 dia
06 .
3d
ia.
2-1
.
2-.02 dia.
47
dia
.
Mounting hole location (Bottom view)
1.2
.047
1.9
.075
Tolerance: ±0.1 ±.004
Schematic
AC type
Input
–
+
Output
General tolerance: ±0.5 ±.020
DC type
Input
–
+
Output
+
–
CAUTIONS FOR USE
1. Regarding output noise surge protection
(1) AC Output Type
A high noise surge voltage applied to the
SSR load circuit can cause malfunction or
permanent damage to the device. If such
a high surge is anticipated, use a varistor
across the SSR output.
2. When used for the load less than rated
An SSR may malfunction if it is used below the specified load. In such an event,
use a dummy resistor in parallel with the
load.
R0 (dummy resistor)
Load
1
Load
power
supply
SSR
1
Load
Load
power
supply
SSR
2
Varistor
(2) DC Output Type
When the SSR is loaded with an inductive
load, such as a solenoid contactor, motor,
or solenoid valve, use a counter-EMF
suppression diode across the load.
2
Load specification: AC output type 20 mA
DC output type 1 mA
3. Noise and surge protection at the input side
A high noise surge voltage applied to the
SSR input circuit can cause malfunction
or permanent damage to the device. If
such a high surge is anticipated, use C or
R noise absorber in the input circuit.
4. When the input terminals are connected with reverse polarity
Reversing the polarity may cause permanent damage to the device. Take special
care to avoid polarity reversal or use a
protection diode in the input circuit.
5. In the case of operating voltage containing ripple
If the SSR control voltage contains ripple,
the peak of the ripple should not exceed
the maximum rated control voltage, and
the bottom of the ripple should exceed the
minimum rated control voltage.
Peak ripple voltage
Valley ripple voltage
0V
R
1
3
Load
Load
power
supply
SSR
Control
voltage
source
C
SSR
2
4
3
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6. Cleaning solvents compatibility
Dip cleaning with an organic solvent is
recommended for removal of solder flux,
dust, etc. Select a cleaning solvent from
the following table. If ultrasonic cleaning
must be used, the severity of factors such
as frequency, output power and cleaning
solvent selected may cause loose wires
and other defects. Make sure these conditions are correct before use. For details,
please consult us.
Cleaning solvent
Chlorinebase
Adueous
Alcoholbase
Others
4
0803/2000
• Trichlene
• Chloroethlene
• Indusco
• Hollis
• Lonco Terg
• IPA
• Ethanol
• Thinner
• Gasoline
Compatibility
❍: Yes
×: No
(
)
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7. Others
(1) If an SSR is used in close proximity to
another SSR or heat-generating device,
its ambient temperature may exceed the
allowable level. Carefully plan SSR layout
and ventilation.
(2) Soldering to SSR terminals should be
completed within 5 seconds at 260°C.
(3) Terminal connections should be made
by referring to the associated wiring diagram.
(4) For higher reliability, check device
quality under actual operating conditions.
8. Thermal Design
SSRs used in high-reliability equipment
require careful thermal design. In particular, junction temperature control has a significant effect on device function and life
time. The rated load current for boardmounting SSRs is defined as the maximum current possible at an ambient temperature of 40°C (30°C) while allowing
natural cooling (self cooling). If the ambient temperature exceeds 40°C (30°C),
load current derating is necessary according to the load current versus ambient
temperature curve. If adjacent devices act
as heat sources, the SSR should be located more than 10 mm away from those devices.
❍
×
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