AQ-B
TÜV Rheinland
AQ-B SOLID STATE RELAY
AQ-B RELAYS
TYPICAL
APPLICATIONS
• Copying equipment
• NC machines, sequencers,
robots
• Air conditioners
FEATURES
43
1.693
9
.354
20
.787
• Two types available: Non zero-cross type and Zero-cross type
Non zero-cross type permits phase control and Zero-cross type
suppresses occurrence of noise.
• Slim type
The small-sized slim type (43 mm long
×
9 mm wide
×
24 mm high)
(1.693×.354×.945 inch)
permits high density mounting to PC board.
• High dielectric strength: 1,500 V AC (between input and output)
4,000 V AC (between input and output)
RoHS Directive compatibility information
http://www.nais-e.com/
TYPES
Type
Load voltage
Input voltage
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
3 to 6 V DC
7 to 14 V DC
10 to 18 V DC
18 to 30 V DC
Standard type (1,500 V AC)
Part No.
AQB1A1-ZT3/6VDC
AQB1A1-ZT7/14VDC
AQB1A1-ZT10/18VDC
AQB1A1-ZT18/30VDC
AQB1A2-ZT3/6VDC
AQB1A2-ZT7/14VDC
AQB1A2-ZT10/18VDC
AQB1A2-ZT18/30VDC
AQB2A1-ZT3/6VDC
AQB2A1-ZT7/14VDC
AQB2A1-ZT10/18VDC
AQB2A1-ZT18/30VDC
AQB2A2-ZT3/6VDC
AQB2A2-ZT7/14VDC
AQB2A2-ZT10/18VDC
AQB2A2-ZT18/30VDC
AQB1A1-T3/6VDC
AQB1A1-T7/14VDC
AQB1A1-T10/18VDC
AQB1A1-T18/30VDC
AQB1A2-T3/6VDC
AQB1A2-T7/14VDC
AQB1A2-T10/18VDC
AQB1A2-T18/30VDC
AQB2A1-T3/6VDC
AQB2A1-T7/14VDC
AQB2A1-T10/18VDC
AQB2A1-T18/30VDC
AQB2A2-T3/6VDC
AQB2A2-T7/14VDC
AQB2A2-T10/18VDC
AQB2A2-T18/30VDC
Reinforced type (4,000 V AC)
Part No.
—
—
—
—
AQB1A2-ZV3/6VDC
AQB1A2-ZV7/14VDC
AQB1A2-ZV10/18VDC
AQB1A2-ZV18/30VDC
—
—
—
—
AQB2A2-ZV3/6VDC
AQB2A2-ZV7/14VDC
AQB2A2-ZV10/18VDC
AQB2A2-ZV18/30VDC
—
—
—
—
AQB1A2-V3/6VDC
AQB1A2-V7/14VDC
AQB1A2-V10/18VDC
AQB1A2-V18/30VDC
—
—
—
—
AQB2A2-V3/6VDC
AQB2A2-V7/14VDC
AQB2A2-V10/18VDC
AQB2A2-V18/30VDC
75 to 125 V AC
Zero-cross 1 A
75 to 250 V AC
75 to 125 V AC
Zero-cross 2 A
75 to 250 V AC
75 to 125 V AC
Non zero-cross 1 A
75 to 250 V AC
75 to 125 V AC
Non zero-cross 2 A
75 to 250 V AC
All Rights Reserved © COPYRIGHT Matsushita Electric Works, Ltd.
AQ-B
ORDERING INFORMATION
Ex. AQB
1A
1
ZT
3/6VDC
Load current
1A
2A
Load voltage
1: 75 to 125 V AC
2: 75 to 250 V AC
Type
ZT: Zero-cross type: 1,500 V
T: Non zero-cross type: 1,500 V
ZV: Zero-cross type: 4,000 V
V: Non zero-cross type: 4,000 V
Input voltage
3/6, 7/14, 10/18,
18/30 V DC
SPECIFICATIONS
Ratings
(at 20°C
68°F,
Input voltage ripple: 1% or less)
1. Zero-cross type
1 A type
Part No.
Item
Input side
Input voltage
Input impedance
Drop-out voltage,
min.
Max. load current
Load voltage
Frequency
Repetitive peak
voltage, max.
Non-repetitive
surge current
“OFF-state”
leakage current
Max. “ON-state”
voltage drop
Min. load current
OFF state dV/dt
AQB1A2-ZT AQB1A2-ZT AQB1A2-ZT AQB1A2-ZT
AQB1A1-ZT AQB1A1-ZT AQB1A1-ZT AQB1A1-ZT
3/6VDC
7/14VDC
10/18VDC
18/30VDC
3/6VDC
7/14VDC
10/18VDC
18/30VDC AQB1A2-ZV AQB1A2-ZV AQB1A2-ZV AQB1A2-ZV
3/6VDC
7/14VDC
10/18VDC
18/30VDC
3 to
7 to
10 to
18 to
3 to
7 to
10 to
18 to
6 V DC
14 V DC
18 V DC
30 V DC
6 V DC
14 V DC
18 V DC
30 V DC
Approx.
Approx.
Approx.
Approx.
Approx.
Approx.
Approx.
Approx.
0.18 kΩ
0.75 kΩ
1.2 kΩ
2.15 kΩ
0.18 kΩ
0.75 kΩ
1.2 kΩ
2.15 kΩ
1V
1A
75 to 125 V AC
45 to 65 Hz
400 V
10A
0.6 mA/100 V applied
1.6 V
10 mA
100 V/µs
20 mA
1.1 mA/200 V applied
600 V
In one cycle
at 60 Hz
at 60 Hz
at max. car-
rying current
75 to 250 V AC
See “DATA 1”
Remarks
2 A type
Part No.
Item
Input side
Input voltage
Input impedance
Drop-out voltage,
min.
Max. load current
Load voltage
Frequency
Repetitive peak
voltage, max.
Non-repetitive
surge current
“OFF-state”
leakage current
Max. “ON-state”
voltage drop
Min. load current
OFF state dV/dt
AQB2A2-ZT AQB2A2-ZT AQB2A2-ZT AQB2A2-ZT
AQB2A1-ZT AQB2A1-ZT AQB2A1-ZT AQB2A1-ZT
3/6VDC
7/14VDC
10/18VDC
18/30VDC
3/6VDC
7/14VDC
10/18VDC
18/30VDC AQB2A2-ZV AQB2A2-ZV AQB2A2-ZV AQB2A2-ZV
3/6VDC
7/14VDC
10/18VDC
18/30VDC
3 to
7 to
10 to
18 to
3 to
7 to
10 to
18 to
6 V DC
14 V DC
18 V DC
30 V DC
6 V DC
14 V DC
18 V DC
30 V DC
Approx.
Approx.
Approx.
Approx.
Approx.
Approx.
Approx.
Approx.
0.18 kΩ
0.75 kΩ
1.2 kΩ
2.15 kΩ
0.18 kΩ
0.75 kΩ
1.2 kΩ
2.15 kΩ
1V
2A
75 to 125 V AC
45 to 65 Hz
400 V
20A
0.6 mA/100 V applied
1.6 V
10 mA
100 V/µs
20 mA
1.1 mA/200 V applied
600 V
In one cycle
at 60 Hz
at 60 Hz
at max. car-
rying current
75 to 250 V AC
See “DATA 1”
Remarks
Load side
Load side
All Rights Reserved © COPYRIGHT Matsushita Electric Works, Ltd.
AQ-B
2. Non zero-cross type
1 A type
Part No.
AQB1A1-T
3/6VDC
Item
Input side
Input voltage
Input impedance
Drop-out voltage,
min.
Max.load current
Load voltage
Frequency
Repetitive peak
voltage, max.
Non-repetitive
surge current
“OFF-state”
leakage current
Max. “ON-state”
voltage drop
Min. load current
OFF state dV/dt
3 to
6 V DC
Approx.
0.18 kΩ
7 to
14 V DC
Approx.
0.75 kΩ
10 to
18 V DC
Approx.
1.2 kΩ
18 to
30 V DC
Approx.
2.15 kΩ
AQB1A1-T
7/14VDC
AQB1A1-T
10/18VDC
AQB1A1-T
18/30VDC
AQB1A2-T
3/6VDC
AQB1A2-V
3/6VDC
3 to
6 V DC
Approx.
0.18 kΩ
AQB1A2-T
7/14VDC
AQB1A2-V
7/14VDC
7 to
14 V DC
Approx.
0.75 kΩ
AQB1A2-T
10/18VDC
AQB1A2-V
10/18VDC
10 to
18 V DC
Approx.
1.2 kΩ
AQB1A2-T
18/30VDC
AQB1A2-V
18/30VDC
18 to
30 V DC
Approx.
2.15 kΩ
Remarks
1V
1A
75 to 125 V AC
45 to 65 Hz
400 V
10A
0.6 mA/100 V applied
1.6 V
10 mA
100 V/µs
20 mA
1.1 mA/200 V applied
600 V
In one cycle
at 60 Hz
at 60 Hz
at max. car-
rying current
75 to 250 V AC
See “DATA 1”
2 A type
Part No.
AQB2A1-T
3/6VDC
Item
Input side
Input voltage
Input impedance
Drop-out voltage,
min.
Max.load current
Load voltage
Frequency
Repetitive peak
voltage, max.
Non-repetitive
surge current
“OFF-state”
leakage current
Max. “ON-state”
voltage drop
Min. load current
OFF state dV/dt
3 to
6 V DC
Approx.
0.18 kΩ
7 to
14 V DC
Approx.
0.75 kΩ
10 to
18 V DC
Approx.
1.2 kΩ
18 to
30 V DC
Approx.
2.15 kΩ
AQB2A1-T
7/14VDC
AQB2A1-T
10/18VDC
AQB2A1-T
18/30VDC
AQB2A2-T
3/6VDC
AQB2A2-V
3/6VDC
3 to
6 V DC
Approx.
0.18 kΩ
AQB2A2-T
7/14VDC
AQB2A2-V
7/14VDC
7 to
14 V DC
Approx.
0.75 kΩ
AQB2A2-T
10/18VDC
AQB2A2-V
10/18VDC
10 to
18 V DC
Approx.
1.2 kΩ
AQB2A2-T
18/30VDC
AQB2A2-V
18/30VDC
18 to
30 V DC
Approx.
2.15 kΩ
Remarks
Load side
1V
2A
75 to 125 V AC
45 to 65 Hz
400 V
20A
0.6 mA/100 V applied
1.6 V
10 mA
100 V/µs
20 mA
1.1 mA/200 V applied
600 V
In one cycle
at 60 Hz
at 60 Hz
at max. car-
rying current
75 to 250 V AC
See “DATA 1”
Characteristics
(at 20°C
68°F,
Input voltage ripple: less than 1%)
Item
Operate time, max.
Release time, max.
Insulation resistance, min.
Breakdown voltage
Vibration resistance
Shock resistance
Ambient temperature
Storage temperature
Operational method
Functional
Destructive
Functional
Destructive
Zero-cross type
Non zero-cross type
Standard type
Reinforced type
Standard type
Reinforced type
(1/2 cycle of voltage sine wave) +1 ms
0.5 ms
(1/2 cycle of voltage sine wave) +1 ms
10
9
Ω
between input and output
1,500 V AC
4,000 V AC
1,500 V AC
4,000 V AC
between input
between input
between input
between input
and output
and output
and output
and output
10 to 55 Hz at double amplitude of 3 mm
10 to 55 Hz at double amplitude of 3 mm
Min. 980 m/s
2
{100 G}
Min. 980 m/s
2
{100 G}
–20°C to +80°C
–4°F to +176°F
–25°C to +85°C
–13°F to +185°F
Zero-cross Turn-ON
Random Turn-ON
Zero-cross Turn-OFF
Zero-cross Turn-OFF
Remarks
Load side
For 1 minute
10 minutes for X, Y, Z axes
1 hour for X, Y, Z axes
4 times for X, Y, Z axes
5 times for X, Y, Z axes
All Rights Reserved © COPYRIGHT Matsushita Electric Works, Ltd.
AQ-B
OPERATING PRINCIPLE
Internal circuit
Zero-cross type
+
Trigger circuit
Phototriac
coupler
Zero-
cross
circuit
Snubber circuit
Load voltage
Triac
R Output
terminal
C
Input signal
Load current
ON
OFF
Wave form of input and output (Resistive load)
Input
Input
terminal circuit
_
Non zero-cross type
+
Input
Input
terminal circuit
Snubber circuit
Trigger circuit
Phototriac
coupler
Load voltage
Triac
R Output
terminal
C
Input signal
Load current
ON
OFF
_
DIMENSIONS
(Common for zero-cross and
Non zero-cross type)
PC board pattern (BOTTOM VIEW)
Max. 43
1.693
Max. 9
.354
Copper foil
4
Max. 20
.787
4
.157
5.0
.197
0.5
.020
Max. 2
.079
12.5
.492
3
27.5
1.083
2
Terminal
1
10.0
.394
mm
inch
4-1.4 dia.
4-.055 dia.
1
.039
1
.039
3.75
.148
5
12.5
.197 .492
1
.039
10
.394
1
.039
Terminal connection diagram
INPUT
4 3
1
… Output: AC
2
… Output: AC
3
… Input: DC +
4
… Input: DC –
– +
LOAD
2 1
4
3
2
1
General tolerance:
±0.5
±.020
Load
Input power Load power source
source
REFERENCE DATA
1. Load current vs. ambient temperature
3.0
Non-repetitive surge current, A
2.5
Load current, A
2.0
1.5
1 A type
1.0
0.5
0
–30
2-1. Non-repetitive surge current vs. carrying
time (1 A type)
30
25
20
15
10
5
0
2-2. Non-repetitive surge current vs. carrying
time (2 A type)
30
Non-repetitive surge current, A
25
20
15
10
5
0
2 A type
0
20
40
60
80
Ambient temperature,
°C
1
2
3 4 5 7 10
20 30 40 50 70 100
No. of cycles at 60 Hz
1
2
3 4 5 7 10
20 30 40 50 70 100
No. of cycles at 60 Hz
3. Input current vs. input voltage
4. Load current vs. ambient temperature for adjacent mounting
1 A type
2 A type
45
40
Input current, mA
35
30
25
20
15
10
5
0
0
10
20
Input voltage, V
30
0
0
=Adjacent mounting
1.0
(3 to 6 V type)
Load current, A
Load current, A
=20.32 mm
.800 inch
=12.7 mm
.500 inch
=9.0 mm
.354 inch
2.0
1.5
=20.32 mm
.800 inch
=12.7 mm
.500 inch
=9.0 mm
.354 inch
(7 to 14 V type)
(18 to 30 V type)
(10 to 18 V type)
0.5
1.0
0.5
=Adjacent mounting
20
40
60
80
Ambient temperature,
°C
0
20
40
60
80
Ambient temperature,
°C
All Rights Reserved © COPYRIGHT Matsushita Electric Works, Ltd.
AQ-B
NOTE
When used for the load less than rated
In case of the load current less than
rated, malfunction may result from the
residual voltage across the both ends of
the load even if the solid state relay is
turned off.
Use a dummy resistor as a countermea-
sure.
The total of the current through the
resistor and the load current must exceed
the min. rated load current.
R
0
(dummy resistor)
In case the dummy resistor is not used,
keep in mind that the residual voltage
becomes as follows:
Example:
For the inductive load by the 5 mA load
current and the 200 V AC load voltage,
the load impedance becomes 40 k
Ω
and
Ve/V = 16% is estimated from the right
above graph. Accordingly, the 32 V
voltage remains across the both ends of
the load when the solid state relay is
turned off.
• Characteristics of residual voltage vs.
load impedance
100
f = 60 Hz
Ve: Residual voltage
V: Power voltage
1
60
Ve
×
100 ,
V
%
40
SSR
2
Load
Ve
V
80
20
1
SSR
2
Load
Load
power
source
0
10
20
Power factor: 1
(resistive load)
Power factor: 0.4
(inductive load)
30
40
50
Load impedance, kΩ
For Cautions for Use
All Rights Reserved © COPYRIGHT Matsushita Electric Works, Ltd.
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