Notes: 1. Reverse polarity types available (add suffix-R)
2. Certified by UL, CSA and TÜV
Panasonic Corporation
Automation Controls Business Unit
industrial.panasonic.com/ac/e/
ASCTB180E 201202-T
DSP
TYPES
Contact
arrangement
Nominal coil
voltage
3V DC
5V DC
1 Form A
6V DC
9V DC
12V DC
24V DC
3V DC
5V DC
1 Form A
1 Form B
6V DC
9V DC
12V DC
24V DC
3V DC
5V DC
2 Form A
6V DC
9V DC
12V DC
24V DC
Single side stable
Part No.
DSP1a-DC3V
DSP1a-DC5V
DSP1a-DC6V
DSP1a-DC9V
DSP1a-DC12V
DSP1a-DC24V
DSP1-DC3V-F
DSP1-DC5V-F
DSP1-DC6V-F
DSP1-DC9V-F
DSP1-DC12V-F
DSP1-DC24V-F
DSP2a-DC3V
DSP2a-DC5V
DSP2a-DC6V
DSP2a-DC9V
DSP2a-DC12V
DSP2a-DC24V
2 coil latching
Part No.
DSP1a-L2-DC3V
DSP1a-L2-DC5V
DSP1a-L2-DC6V
DSP1a-L2-DC9V
DSP1a-L2-DC12V
DSP1a-L2-DC24V
DSP1-L2-DC3V-F
DSP1-L2-DC5V-F
DSP1-L2-DC6V-F
DSP1-L2-DC9V-F
DSP1-L2-DC12V-F
DSP1-L2-DC24V-F
DSP2a-L2-DC3V
DSP2a-L2-DC5V
DSP2a-L2-DC6V
DSP2a-L2-DC9V
DSP2a-L2-DC12V
DSP2a-L2-DC24V
Standard packing: Carton: 50 pcs.; Case: 500 pcs.
Note: Reverse polarity type are manufactured by lot upon receipt of order. Self-clinching types are also available, please consult us.
* For sockets, see page 100.
RATING
1. Coil data
1) Single side stable
Nominal coil
voltage
3V DC
5V DC
6V DC
9V DC
12V DC
24V DC
80%V or less of
nominal voltage
(Initial)
10%V or more of
nominal voltage
(Initial)
Pick-up voltage
(at 20°C
68°F)
Drop-out voltage
(at 20°C
68°F)
Nominal operating
current
[±10%] (at 20°C
68°F)
100mA
60mA
50mA
33.3mA
25mA
12.5mA
Coil resistance
[±10%] (at 20°C
68°F)
30Ω
83Ω
120Ω
270Ω
480Ω
1,920Ω
130%V of
nominal voltage
Nominal operating
power
Max. applied voltage
(at 20°C
68°F)
300mW
2) 2 coil latching
Nominal coil
voltage
3V DC
5V DC
6V DC
9V DC
12V DC
24V DC
80%V or less of
nominal voltage
(Initial)
80%V or less of
nominal voltage
(Initial)
Set voltage
(at 20°C
68°F)
Reset voltage
(at 20°C
68°F)
Nominal operating
current
[±10%] (at 20°C
68°F)
Set coil
Reset coil
100mA
60mA
50mA
33.3mA
25mA
12.5mA
100mA
60mA
50mA
33.3mA
25mA
12.5mA
Coil resistance
[±10%] (at 20°C
68°F)
Set coil
30Ω
83Ω
120Ω
270Ω
480Ω
1,920Ω
Reset coil
30Ω
83Ω
120Ω
270Ω
480Ω
1,920Ω
130%V of
nominal voltage
Nominal operating
power
Set coil
Reset coil
Max. applied voltage
(at 20°C
68°F)
300mW
300mW
ASCTB180E 201202-T
Panasonic Corporation
Automation Controls Business Unit
industrial.panasonic.com/ac/e/
DSP
2. Specifications
Characteristics
Contact
Item
Arrangement
Contact resistance (Initial)
Contact material
Nominal switching capacity (resistive load)
Max. switching power (resistive load)
Rating
Max. switching voltage
Max. switching current
Nominal operating power
Min. switching capacity (Reference value)*
1
Insulation resistance (Initial)
Between open contacts
Breakdown voltage
(Initial)
Electrical
characteristics
Between contact sets
Between contact and coil
8 A AC, 5 A DC
300 mW
10m A 5 V DC
Min. 1,000MΩ (at 500V DC) Measurement at same location as “Breakdown voltage” section.
1,000 Vrms for 1min. (Detection current: 10mA.)
2,000 Vrms (1 Form A 1 Form B, 2 Form A) (Detection current: 10mA.)
3,000 Vrms for 1min. (Detection current: 10mA.)
5,000 V
Max. 55°C
Max. 40°C
Max. 55°C
8 A 250 V AC, 5A 30V DC
2,000 VA, 150 W
1 Form A
Specifications
1 Form A 1 Form B
Max. 30 mΩ (By voltage drop 6 V DC 1A)
Au-flashed AgSnO
2
type
5 A 250 V AC, 5 A 30 V DC
1,250 VA, 150 W
250 V AC, 125 V DC
5 A AC, DC
2 Form A
Surge breakdown
between contacts and coil
voltage*
2
Temperature rise (coil) (at 65°C
149°F)
Operate time [Set time] (at 20°C
68°F)
Release time [Reset time] (at 20°C
68°F)
Shock resistance
Functional
Destructive
Functional
Destructive
Max. 10 ms [10 ms] (Nominal coil voltage applied to the coil, excluding contact bounce time.)
Max. 5 ms [10 ms] (Nominal coil voltage applied to the coil, excluding contact bounce time.)
(without diode)
Min. 196 m/s
2
(Half-wave pulse of sine wave: 11 ms; detection time: 10µs.)
Min. 980 m/s
2
(Half-wave pulse of sine wave: 6 ms.)
10 to 55 Hz at double amplitude of 2 mm (Detection time: 10µs.)
10 to 55 Hz at double amplitude of 3.5 mm
Min. 5×10
7
(at 180 times/min.)
Min. 10
5
(resistive load)
Ambient temperature:
Ambient temperature:
Ambient temperature:
–40°C to +60°C
–40°C to +65°C
–40°C to +60°C
–40°F to +140°F
–40°F to +149°F
–40°F to +140°F
250°C
482°F
(10s), 300°C
572°F
(5s), 350°C
662°F
(3s)
(Soldering depth: 2/3 terminal pitch)
3 cps
Approx. 4.5 g
.16 oz
Mechanical
characteristics
Vibration resistance
Expected life
Mechanical
Electrical
Conditions for operation, transport and storage*
3
(Not freezing and condensing at low temperature)
Conditions
Solder heating
Max. operating speed
Unit weight
Notes: *1. This value can change due to the switching frequency, environmental conditions, and desired reliability level, therefore it is recommended to check this with the
actual load.
*2. Wave is standard shock voltage of
±1.2×50µs
according to JEC-212-1981
*3. The upper limit of the ambient temperature is the maximum temperature that can satisfy the coil temperature rise value. Refer to Usage, transport and storage
conditions in NOTES.
REFERENCE DATA
1. Max. switching capacity
10
AC resistive
load (1a)
No. of operations,
×10
4
100
265 V·130 V AC cosϕ = 1
AC resistive
load
(1a1b,2a)
2.-(1) Life curve (1 Form A 1 Form B)
2.-(2) Life curve (1 Form A 1 Form B)
No. of operations,
×10
4
Contact current, V
100
50
30 V DC L/R = 7 ms
30 V DC resistive
DC resistive
load (1a)
1
DC resistive load
(1a1b,2a)
10 265 V·130 V AC
cosϕ = 0.4
10
0.1
10
100
Contact voltage, V
1000
0
1
2
3
4
5
6
Switching capacity, A
7
0.5
1
5
Switching capacity, A
10
3.-(1) Coil temperature rise (1 Form A)
Tested sample: DSP1a-DC12V, 5 pcs.
60
Coil temperature rise,
°C
3.-(2) Coil temperature rise
(1 Form A 1 Form B)
Tested sample: DSP1-DC12V, 5 pcs.
60
Coil temperature rise,
°C
3.-(3) Coil temperature rise (2 Form A)
Tested sample: DSP2a-DC12V, 5 pcs.
60
Coil temperature rise,
°C
50
40
30
20
10
0
5A
0A
50
40
30
20
10
0
8A
0A
50
40
30
20
10
0
5A
0A
80
100
120
Coil applied voltage, %V
80
100
120
Coil applied voltage, %V
80
100
120
Coil applied voltage, %V
Panasonic Corporation
Automation Controls Business Unit
industrial.panasonic.com/ac/e/
ASCTB180E 201202-T
DSP
4.-(1) Operate & release time
(without diode, 1 Form A)
Tested sample: DSP1a-DC12V, 5 pcs.
7
Operate & release time, ms
6
5
Operate time
4
3
2
1
0
Max.
x
Min.
Release time
Max.
x
Min.
80
100
120
Coil applied voltage, %V
Operate & release time, ms
4.-(2) Operate & release time
(without diode, 1 Form A 1 Form B)
Tested sample: DSP1-DC12V, 5 pcs.
9
4.-(3) Operate & release time
(without diode, 2 Form A)
Tested sample: DSP2a-DC12V, 5 pcs.)
9
Operate & release time, ms
8
7
6
Operate time
5
4
3
2
1
0
80
Release time
Max.
x
Min.
Max.
x
Min.
8
7
6
5
4
3
2
1
0
80
Release time
Max.
x
Min.
Max.
x
Min.
Operate time
100
110
Coil applied voltage, %V
100
120
Coil applied voltage, %V
4.-(4) Operate & release time
(with diode, 1 Form A)
Tested sample: DSP1a-DC12V, 5 pcs.
9
Operate & release time, ms
4.-(5) Operate & release time
(with diode, 1 Form A 1 Form B)
Tested sample: DSP1-DC12V, 5 pcs.
9
Operate & release time, ms
4.-(6) Operate & release time
(with diode, 2 Form A)
Tested sample: DSP2a-DC12V, 5 pcs.
9
Operate & release time, ms
8
7
6
5
4
3
2
1
0
80
Release time
100
120
Max.
x
Min.
Max.
x
Min.
Operate time
8
7
6
5
4
3
2
Release time
1
0
80
100
120
Coil applied voltage, %V
Operate time
Max.
x
Min.
Max.
x
Min.
8
7
6
5
4
3
2
1
0
80
Release time
100
110
Coil applied voltage, %V
Max.
Max.
x
x
Min.
Min.
Operate time
Coil applied voltage, %V
5.-(1) Change of pick-up and drop-out voltage
(1 Form A)
Tested sample: DSP1a-DC12V, 5 pcs.
(%)
Rate of change
5.-(2) Change of pick-up and drop-out voltage
(1 Form A 1 Form B)
Tested sample: DSP1-DC12V, 5 pcs.
(%)
Rate of change
5.-(3) Change of pick-up and drop-out voltage
(2 Form A)
Tested sample: DSP2a-DC12V, 5 pcs.
(%)
Rate of change
50
Drop-out
voltage
Pick-up voltage
–40 –20
50
Pick-up voltage
50
Drop-out
voltage
Pick-up voltage
–40 –20
0
20 40
60 80
Ambient
temperature,
°C
0
20 40
60
80
Ambient
temperature,
°C
–40 –20
0
20 40
60 80
Ambient
temperature,
°C
–50
Drop-out voltage
–50
–50
6.-(1) Influence of adjacent mounting
(1 Form A)
Tested sample: DSP1a-DC12V, 5 pcs.
15
Pick-up voltage
10
Rate of change, %
5
A
B
C
6.-(2) Influence of adjacent mounting
(1 Form A 1 Form B)
Tested sample: DSP1-DC12V, 5 pcs.
10
8
6
Rate of change, %
4
2
0
0
–2
–4
–6
–8
–10
Pick-up voltage
A
B
C
6.-(3) Influence of adjacent mounting
(2 Form A)
Tested sample: DSP2a-DC12V, 5 pcs.
15
Pick-up voltage
10
Rate of change, %
5
A
B
C
15
Drop-out voltage
10
5
A, C
relays
are not
energized
A, C
relays
are
energized
A, C
relays
are not
energized
Drop-out voltage
A, C
relays
are
energized
15
Drop-out voltage
10
5
A, C
relays
are not
energized
A, C
relays
are
energized
0
5
10
Inter-relay distance ( ), mm
1
2
3
4
5
6
Inter-relay distance ( ), mm
0
5
10
Inter-relay distance ( ), mm
ASCTB180E 201202-T
Panasonic Corporation
Automation Controls Business Unit
industrial.panasonic.com/ac/e/
DSP
DIMENSIONS
(mm
inch)
1. 1 Form A type
CAD Data
Single side stable
20.2
.795
The CAD data of the products with a
CAD Data
mark can be downloaded from: http://industrial.panasonic.com/ac/e/
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