PhotoIC Coupler
(AlGaAs LED & PhotoIC)
20 Mbps type
(APS1, APS2)
FEATURES
New
1. Low input voltage and low power consumption achieved
2. High speed Photo Coupler with receiver circuit IC
3. Capable of high speed communication
(Transfer rate Typ. 20 Mbps)
4. Low power consumption:
LED forward current: 6 to 12 mA
Supply current: Max. 3 mA
5. High noise immunity (CMTI Min. 20 kV/μs)
6. Guaranteed performance at high temperature
(-40 to +105°C -40 to +221°F)
7. Isolation voltage: 3,750 Vrms
8. Totem pole and Open drain output types available
2.2
.087
4.4
.173
4.3
.169
Totem pole output
Vcc
1
Vout
GND
2
mm inch
Open drain output
5
Vcc
1
Vout
4
3
GND
2
Control circuit
Truth table
LED
ON
OFF
Output
L
H
5
4
3
Control circuit
Truth table
LED
ON
OFF
TYPICAL APPLICATIONS
Output
L
H
1. Measuring equipment
2. FA (Factory Automation) network
3. I/O of high speed communication
4. Microcomputer communication (SPI, I2C)
RoHS compliant
*Does not support automotive application
TYPES
Figure of output
Transfer rate
Supply voltage
Typ. 20 Mbps
3 to 5 V DC
Totem pole output
Open drain output
Tube packing style
Part No.
Tape and reel packing style
Picked from the
Picked from the
1/2-pin side
3/4/5-pin side
APS1241S
APS1241SX
APS1241SZ
APS2241S
APS2241SX
APS2241SZ
–1–
Packing quantity
Tube
Tape and reel
1 tube contains:
100 pcs.
1 batch contains:
2,000 pcs.
1,000 pcs.
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
RATING Totem pole output
1. Absolute maximum ratings (Ta = 25°C 77°F)
Item
LED forward current
Input
LED reverse voltage
Peak forward current
Supply voltage
Output voltage
Output
Output current
Power dissipation
I/O isolation voltage
Operating
Ambient
temperature
Storage
Symbol
IF
VR
IFP
VCC
VO
IO
Pout
Viso
Topr
Tstg
APS1241S
25 mA
5V
1A
6V
6V
10 mA
40 mW
3,750 V rms
–40 to +105°C –40 to +221°F
–40 to +125°C –40 to +257°F
Remarks
f = 100 Hz, Duty factor = 0.1%, 1 shot
(Non-icing at low temperatures)
2. Electrical characteristics (Unless otherwise specified, Ta = -40 to 105°C -40 to 221°F, VCC = 2.7 to 5.5V)
Item
Threshold input current
Input
Output
LED dropout voltage
Input capacitance
Low level supply current
High level supply current
Low level output voltage
High level output voltage
Item
Propagation delay time
(H ➝ L)
Propagation delay time
(L ➝ H)
Propagation delay skew
Transfer
characteristics
Max.
Min.
Typ.
Max.
Typ.
Max.
Max.
Max.
Min.
Symbol
IFHL
Ct
ICCL
ICCH
VOL
VOH
APS1241S
4 mA
1.45 V
1.6 V
1.8 V
20 pF
3 mA
3 mA
0.4 V
4V
VF
Symbol
APS1241S
Max.
tpHL
55 ns
Max.
tpLH
55 ns
Max.
tpsk
30 ns
Pulse width distortion
Max.
|tpHL-tpLH|
30 ns
Output fall time
Typ.
tf
2 ns
Output rise time
Typ.
tr
2 ns
Min.
CML
20 kV/μs
Min.
CMH
20 kV/μs
Typ.
Min.
Ciso
Riso
0.5 pF
1,000 MΩ
Common mode transient
immunity at low level output
Common mode transient
immunity at high level output
I/O capacitance
Initial I/O isolation resistance
–2–
Condition
VCC = 5 V, VO < 0.4 V
IF = 10 mA, Ta = 25°C 77°F
f = 1 MHz, VB = 0 V, Ta = 25°C 77°F
IF = 9 mA
IF = 0 mA
IF = 9 mA, IO = 4 mA, VCC = 5V
IF = 0 mA, IO = -4 mA, VCC = 5 V
Condition
VIN = 0 ➝ 2.5 V, RIN = 100 Ω
CIN = 15 pF, CO = 15 pF
VIN = 2.5 ➝ 0 V, RIN = 100 Ω
CIN = 15 pF, CO = 15 pF
—
VIN = 2.5 V/10 MHz, RIN = 100 Ω
CIN = 15 pF, CO = 15 pF
VIN = 0 ➝ 2.5 V, RIN = 100Ω
CIN = 15 pF, CO = 15 pF
VIN = 2.5 ➝ 0 V, RIN = 100 Ω
CIN = 15 pF, CO = 15 pF
VCM = 1000 Vp-p′, IF = 9 mA, VCC = 5 V
VO(MAX) = 0.4 V, Ta = 25°C 77°F
VCM = 1000 Vp-p′, IF = 0 mA, VCC = 5 V
VO(MIN) = 4 V, Ta = 25°C 77°F
f = 1 MHz, VB = 0 V, Ta = 25°C 77°F
DC 500V, RH 60 %, Ta = 25°C 77°F
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
Control circuit
0.1 μF
IF
A ICCL
VCC
IF
0.1μF
0.1μF
A ICCH
VCC
Test circuit for VOH
Control circuit
Test circuit for VOL
Control circuit
Test circuit for ICCH
Control circuit
Test circuit for ICCL
0.1μF
VCC
IO
V VOL
VCC
V VOH
IO
Test circuit for propagation delay time
VIN = 0 2.5 V
f = 10 MHz
Duty factor = 50%
t r=5.0ns
90%
50%
10%
VIN
Control circuit
C IN
t f=5.0ns
0.1μF
0V
tf
VOH
VCC
tr
90%
50%
10%
CO
VOUT
RIN
t pLH
t pHL
Test circuit for common mode transient immunity
tr
tf
1kV
90%
Control circuit
VCM
0.1μF
VCC
10%
VO
5V I =0mA
F
4V
VO
0.4V
CM H=
VCM
800(V)
t r(μs)
CM L=
0V
-800(V)
IF=9mA
t f(μs)
RECOMMENDED OPERATING CONDITIONS
Item
LED forward current
Symbol
IF
Min.
6
Max.
12
Unit
mA
Supply voltage
LED off voltage
VCC
VF(OFF)
2.7
0
5.5
0.8
V
V
Please use under recommended operating conditions to obtain expected characteristics.
Additionally, please check other conditions in this specification sheets because they are affected by the actual usage.
–3–
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
REFERENCE DATA Totem pole output
1. LED forward current vs. ambient
temperature characteristics
2. LED forward current vs. LED drop out
voltage characteristics
3. Threshold input current vs. ambient
temperature characteristics
Permissible ambient temperature: –40 to +105 °C
–40 to +221 °F
Permissible ambient temperature: –40 to +105 °C
–40 to +221 °F
Supply voltage: 5 V
Output voltage: < 0.4 V
100
40
30
20
5
Threshold input current, mA
LED forward current, mA
LED forward current, mA
50
10
Ta=105°C
85°C
50°C
25°C
0°C
-25°C
-40°C
1
10
4
3
2
1
0
-40 -20
0
20
40
60
80
0
1
100 105 120
1.2
Ambient temperature, °C
1.4
1.6
1.8
2
0
2.2
-40 -20
0
20
40
60
80
100 105 120
Ambient temperature, °C
LED drop out voltage, V
5. Low level output voltage vs. ambient
temperature characteristics
6. High level output voltage vs. ambient
temperature characteristics
Supply voltage: 5 V
Supply voltage: 5 V; LED current: 9 mA
Output current: 4 mA
Supply voltage: 5 V; LED current: 0 mA
Output current: -4 mA
5
5
4
3
2
ICCL (IF=9 mA)
High level output voltage, V
0.4
Low level output voltage, V
Low level/high level supply current, mA
4. Low level/high level supply current vs.
ambient temperature characteristics
0.3
0.2
0.1
1
0
0
20
40
60
0
100 105 120
80
3
2
1
ICCH (IF=0 mA)
-40 -20
4
-40 -20
Ambient temperature, °C
0
20
40
60
80
0
100 105 120
-40 -20
Ambient temperature, °C
0
20
40
60
80
100 105 120
Ambient temperature, °C
7. Propagation delay time (H ➝ L/L ➝ H) vs.
ambient temperature characteristics
8. Pulse width distortion vs. ambient
temperature characteristics
9. Propagation delay time(H ➝ L/L ➝ H) vs.
LED forward current characteristics
Supply voltage: 5 V
LED current: 9 mA
Supply voltage: 5 V
LED current: 9 mA
Supply voltage: 5 V
Ambient temperature: 25 °C 77 °F
60
50
40
tpLH
30
tpHL
20
Propagation delay time, ns
40
Pulse width distortion, ns
Propagation delay time, ns
60
20
0
50
40
tpLH
30
20
tpHL
-20
10
0
10
-40 -20
0
20
40
60
80
100 105 120
Ambient temperature, °C
-40
-40 -20
0
20
40
60
80
100 105 120
Ambient temperature, °C
0
6
7
8
9
10
11
12
LED forward current, mA
10. Pulse width distortion vs. LED forward
current characteristics
Supply voltage: 5 V
Ambient temperature: 25 °C 77 °F
Pulse width distortion, ns
40
20
0
-20
-40
6
7
8
9
10
11
12
LED forward current, mA
–4–
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
RATING Open drain output
1. Absolute maximum ratings (Ta = 25°C 77°F)
Item
LED forward current
Input
LED reverse voltage
Peak forward current
Supply voltage
Output voltage
Output
Output current
Power dissipation
I/O isolation voltage
Operating
Ambient
temperature
Storage
Symbol
IF
VR
IFP
VCC
VO
IO
Pout
Viso
Topr
Tstg
APS2241S
25 mA
5V
1A
6V
6V
25 mA
40 mW
3,750 V rms
–40 to +105°C –40 to +221°F
–40 to +125°C –40 to +257°F
Remarks
f = 100 Hz, Duty factor = 0.1%, 1 shot
(Non-icing at low temperatures)
2. Electrical characteristics (Unless otherwise specified, Ta = -40 to 105°C -40 to 221°F, VCC = 2.7 to 5.5V)
Item
Threshold input current
Input
Output
LED dropout voltage
Input capacitance
Low level supply current
High level supply current
Low level output voltage
High level output current
Item
Propagation delay time
(H ➝ L)
Propagation delay time
(L ➝ H)
Propagation delay skew
Transfer
characteristics
Max.
Min.
Typ.
Max.
Typ.
Max.
Max.
Max.
Max.
Symbol
IFHL
Ct
ICCL
ICCH
VOL
IOH
APS2241S
4 mA
1.45 V
1.6 V
1.8 V
20 pF
3 mA
3 mA
0.6 V
50 μA
VF
Symbol
APS2241S
Max.
tpHL
60 ns
Max.
tpLH
60 ns
Max.
tpsk
40 ns
Pulse width distortion
Max.
|tpHL-tpLH|
35 ns
Output fall time
Typ.
tf
1 ns
Output rise time
Typ.
tr
18 ns
Min.
CML
20 kV/μs
Min.
CMH
20 kV/μs
Typ.
Min.
Ciso
Riso
0.5 pF
1,000 MΩ
Common mode transient
immunity at low level output
Common mode transient
immunity at high level output
I/O capacitance
Initial I/O isolation resistance
–5–
Condition
VCC = 5 V, VO < 0.6 V
IF = 10 mA, Ta = 25°C 77°F
f = 1 MHz, VB = 0 V, Ta = 25°C 77°F
IF = 9 mA
IF = 0 mA
IF = 9 mA, IO = 13 mA, VCC = 5V
IF = 0 mA, VCC = 5.5 V, VO = 5.5 V
Condition
VIN = 0 ➝ 2.5 V, RIN = 100 Ω
CIN = 15 pF, RO = 360 Ω, CO = 15 pF
VIN = 2.5 ➝ 0 V, RIN = 100 Ω
CIN = 15 pF, RO = 360 Ω, CO = 15 pF
—
VIN = 2.5 V/5 MHz, RIN = 100 Ω
CIN = 15 pF, RO = 360 Ω, CO = 15 pF
VIN = 0 ➝ 2.5 V, RIN = 100Ω
CIN = 15 pF, RO = 360 Ω, CO = 15 pF
VIN = 2.5 ➝ 0 V, RIN = 100 Ω
CIN = 15 pF, RO = 360 Ω, CO = 15 pF
VCM = 1000 Vp-p′, IF = 9 mA, VCC = 5 V
VO(MAX) = 0.8 V, Ta = 25°C 77°F
VCM = 1000 Vp-p′, IF = 0 mA, VCC = 5 V
VO(MIN) = 2 V, Ta = 25°C 77°F
f = 1 MHz, VB = 0 V, Ta = 25°C 77°F
DC 500V, RH 60 %, Ta = 25°C 77°F
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
0.1μF
A ICCL
VCC
0.1μF
0.1μF
A ICCH
VCC
Test circuit for IOH
Control circuit
Test circuit for VOL
Control circuit
IF
Control circuit
Test circuit for ICCH
Control circuit
Test circuit for ICCL
IF
0.1μF
VCC
V VOL
IO
A
I OH
VCC
VO
Test circuit for propagation delay time
VIN = 0 2.5 V
f = 5 MHz
Duty factor = 50%
t r=5.0ns
t f=5.0ns
90%
50%
10%
Control circuit
VIN
C IN
RO
0V
0.1μF
tf
VOH
VCC
VO
CO
tr
90%
50%
10%
VOUT
RIN
t pLH
t pHL
Test circuit for common mode transient immunity
tr
tf
1kV
Control circuit
90%
VCM
RO
0.1μF
10%
VCC
VO
5V I =0mA
F
2V
CO
VO
0.8V
VCM
CM H=
800(V)
t r(μs)
CM L=
0V
-800(V)
IF=9 mA
t f(μs)
RECOMMENDED OPERATING CONDITIONS
Item
LED forward current
Symbol
IF
Min.
6
Max.
12
Unit
mA
Supply voltage
LED off voltage
VCC
VF(OFF)
2.7
0
5.5
0.8
V
V
Please use under recommended operating conditions to obtain expected characteristics.
Additionally, please check other conditions in this specification sheets because they are affected by the actual usage.
–6–
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
REFERENCE DATA Open drain output
1. LED forward current vs. ambient
temperature characteristics
2. LED forward current vs. LED drop out
voltage characteristics
3. Threshold input current vs. ambient
temperature characteristics
Permissible ambient temperature: –40 to +105 °C
–40 to +221 °F
Permissible ambient temperature: –40 to +105 °C
–40 to +221 °F
Supply voltage: 5 V
Output voltage: < 0.6 V
100
40
30
20
5
Threshold input current, mA
LED forward current, mA
LED forward current, mA
50
10
Ta=105°C
85°C
50°C
25°C
0°C
-25°C
-40°C
1
10
4
3
2
1
0
-40 -20
0
20
40
60
80
0
1
100 105 120
1.2
Ambient temperature, °C
1.4
1.6
1.8
2
0
2.2
-40 -20
0
20
40
60
100 105 120
80
Ambient temperature, °C
LED drop out voltage, V
5. Low level output voltage vs. ambient
temperature characteristics
6. Propagation delay time (H ➝ L/L ➝ H) vs.
ambient temperature characteristics
Supply voltage: 5 V
Supply voltage: 5 V; LED current: 9 mA
Output current: 13 mA
Supply voltage: 5 V
LED current: 9 mA
5
60
4
3
2
ICCL (IF=9 mA)
Propagation delay time, ns
0.4
Low level output voltage, V
Low level/high level supply current, mA
4. Low level/high level supply current vs.
ambient temperature characteristics
0.3
0.2
50
40
tpLH
30
tpHL
20
0.1
1
0
10
ICCH (IF=0 mA)
-40 -20
0
20
40
60
80
0
100 105 120
-40 -20
Ambient temperature, °C
0
20
40
60
80
0
100 105 120
-40 -20
Ambient temperature, °C
0
20
40
60
80
100 105 120
Ambient temperature, °C
7. Pulse width distortion vs. ambient
temperature characteristics
8. Propagation delay time(H ➝ L/L ➝ H) vs.
LED forward current characteristics
9. Pulse width distortion vs. LED forward
current characteristics
Supply voltage: 5 V
LED current: 9 mA
Supply voltage: 5 V
Ambient temperature: 25 °C 77 °F
Supply voltage: 5 V
Ambient temperature: 25 °C 77 °F
40
20
0
50
40
tpLH
30
20
tpHL
-20
Pulse width distortion, ns
60
Propagation delay time, ns
Pulse width distortion, ns
40
20
0
-20
10
-40
-40 -20
0
20
40
60
80
100 105 120
Ambient temperature, °C
0
6
7
8
9
10
11
LED forward current, mA
–7–
12
-40
6
7
8
9
10
11
12
LED forward current, mA
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
The CAD data of the products with a
Recommended mounting pad (Top view)
6.8±0.4
.268±.016
0.5
.020
4.4±0.2
.173±.008
0.1
.004
2.1±0.2
.083±.008
4.3±0.2
.169±.008
1.27
.050
1.2
.047
0.5
.020
External dimensions
mark can be downloaded from: http://industrial.panasonic.com/ac/e/
0.8
.031
6.0
.236
DIMENSIONS (mm inch)
2.54
.100
Tolerance: ±0.1 ±.004
0.4
.016
1.27
.050
0.4
.016
1.27
.050
Terminal thickness = ±0.15 ±.006
General tolerance: ±0.1 ±.004
–8–
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
CAUTIONS FOR USE
SAFETY WARNINGS
• Do not use the product under conditions that exceed the range
of its specifications. It may cause overheating, smoke, or fire.
• Do not touch the recharging unit while the power is on. There is
a danger of electrical shock. Be sure to turn off the power when
performing mounting, maintenance, or repair operations on the
device (including connecting parts such as the terminal board
and socket).
• Check the connection diagrams in the catalog and be sure to
connect the terminals correctly. Erroneous connections could
lead to unexpected operating errors, overheating, or fire.
1. Please visit our Automation Controls Products web site
and refer to the caution for use and the explanations of
technical terms.
7. Ripple in the input power supply
If ripple is present in the input power supply, please keep the
LED forward current from 6 (at Emin) to 12 mA (at Emax).
2. About derating design
Derating is significant factor concerning on reliable design
(product life). When the coupler is used continuously at upper
limit of absolute maximum ratings (high temperature, high
humidity, high current, high voltage, etc.), reliability may be lower
significantly. Therefore, please derate sufficiently below the
absolute maximum ratings and evaluate the coupler under the
actual condition.
8. Caution for applying supply voltage
Just after supplying voltage, please note that current in the
coupler will be not constant until circuit stability.
3. Wire connection
Please check the internal connection diagram in the catalog or
specification, and connect the terminals correctly. If device is
energized with short-circuit or any wrong connection, it may
cause circuit damage by inner parts destruction, unexpected
malfunction, abnormal heat, fire, and so on.
9. Soldering
(1) IR (Infrared reflow) soldering method
In case of automatic soldering, following conditions should be
observed.
(recommended condition
reflow: Max. 2 times, measurement point: soldering lead)
4. Bypass capacitor
Bypass capacitor of 0.1μF is used between Vcc and GND near
the coupler. Also, ensure that the distance between the leads of
the coupler and capacitor is no more than 10 mm. Failure to
provide the bypass may impair the switching property.
T3
5. Pull up resistor (Open drain output type)
Please connect pull up resistor between Vo and Vcc. The pull up
resistor affects the coupler transfer characteristics. Therefore,
please evaluate the coupler under the actual condition.
6. Deterioration and destruction caused by discharge of
static electricity
This phenomenon is generally called static electricity
destruction, and occurs when static electricity generated by
various factors is discharged while the coupler terminals are in
contact, producing internal destruction of the element.
To prevent problems from static electricity, the following
precautions and measures should be taken when using your
device.
(1) Employees handling the coupler should wear anti-static
clothing and should be grounded through protective resistance
of 500 kΩ to 1 MΩ.
(2) A conductive metal sheet should be placed over the
worktable. Measuring instruments and jigs should be grounded.
(3) When using soldering irons, either use irons with low leakage
current, or ground the tip of the soldering iron.
(Use of low-voltage soldering irons is also recommended.)
(4) Devices and equipment used in assembly should also be
grounded.
(5) When packing printed circuit boards and equipment, avoid
using high-polymer materials such as foam styrene, plastic, and
other materials which carry an electrostatic charge.
(6) When storing or transporting the coupler, the environment
should not be conducive to generating static electricity (for
instance, the humidity should be between 45 and 60 %), and the
coupler should be protected using conductive packing materials.
–9–
Emin.
Emax.
t3
T1 = 150 to 180 °C 302 to 356 °F
T2 = 230 °C 446 °F
T3 = 240 to 250 °C 464 to 482 °F
t1 = 60 to 120 s
t2 = Within 30 s
t3 = Within 10 s
T2
T1
t1
t2
(2) Others soldering methods
Other soldering methods (VPS, hot-air, hot plate, laser heating,
pulse heater, etc.) affect the coupler characteristics differently,
please evaluate the coupler under the actual usage.
(3) Manual soldering method
Soldering: Max. 350 °C 662 °F, within 3 s, electrical power 30 to
60 W
10. Notes for mounting
(1) When different kinds of packages are mounted on PCB, the
temperature rise at soldering lead is highly dependent on
package size. Therefore, please set the lower temperature
soldering condition than above condition, and confirm the
temperature condition of actual usage before soldering.
(2) When soldering condition is out of recommendation, the
coupler characteristics may be adversely affected. It may occur
package crack or bonding wire breaking because of thermal
expansion unconformity and resin strength reduction. Please
contact us about the propriety of the condition.
(3) Please confirm the heat stress by using actual board
because it may be changed by board condition or manufacturing
process condition.
(4) Solder creepage, wettability, or soldering strength will be
affected by the soldering condition or used solder type. Please
check them under the actual production condition in detail.
(5) Please apply coating when the coupler returns to the room
temperature.
ASCTB387E 201703-T
PhotoIC Coupler 20 Mbps type (APS1, APS2)
11. Cleaning solvents compatibility
Cleaning the solder flux should use the immersion washing with
an cleaning solvent (Asahiklin AK-225). If you have to use
ultrasonic cleaning, please adopt the following conditions and
check that there are no problems in the actual usage.
• Frequency: 27 to 29 kHz
• Ultrasonic output: No greater than 0.25 W/cm2*
• Cleaning time: 30 s or less
• Others: Float PCB and the device in cleaning solvent to prevent
from contacting the ultrasonic vibrator.
*Note: Applies to unit area of ultrasonic output for ultrasonic baths.
12. Transportation and storage
(1) Extreme vibration during transport may deform the lead or
damage the coupler. Please handle the outer and inner boxes
with care.
(2) Inadequate storage condition may degrade soldering,
appearance and characteristics.
The following storage conditions are recommended:
• Temperature: 0 to 45 °C 32 to 113 °F
• Humidity: Max. 70 %RH
• Atmosphere: No harmful gasses such as sulfurous acid gas
and not dusty.
(3) In case the heat stress of soldering is applied to the coupler
which absorb moisture inside of its package, the evaporation of
the moisture increases the pressure inside the package and it
may cause the package blister or crack. This coupler is sensitive
to moisture and it is packed in the sealed moisture-proof
package. Please make sure the following condition after
unsealing.
*Please use the coupler immediately after unsealing. (within 30
days at 0 to 30 °C 32 to 86 °F and Max. 70%RH)
*If the coupler will be kept for a long time after unsealing, please
pack in the another moisture-proof package containing silica gel
and store. (Please use within 90days)
13. Water condensation
Water condensation occurs when the ambient temperature
changes suddenly from a high temperature to low temperature
at high humidity, or the coupler is suddenly transferred from a
low ambient temperature to a high temperature and humidity.
Condensation causes the failures such as insulation
deterioration. Panasonic Corporation does not guarantee the
failures caused by water condensation.
The heat conduction by the equipment the coupler is mounted
may accelerate inside equipment water condensation. Please
confirm no that there are condensation in the worst condition of
the actual usage.
(Special attention should be paid when high temperature heating
parts are close to the coupler.)
14. Coupler packaging format
1) Tape and reel (Unit: mm inch)
Tape dimensions
7.2±0.1
.283±.004
80±1 dia.
3.150±.039 dia.
254±2 dia.
10.000±.079 dia.
4±0.1
.157±.004
12±0.3
.472±.012
Device mounted
on tape
2.8±0.3
.110±.012
13±0.5 dia.
.512±.020 dia.
Direction of picking
1.75±0.1
.069±.004
5.5±0.1
.217±.004
4.7±0.1
.185±.004
0.3±0.05
.012±.002
Tractor feed holes
1.55±0.05 dia.
.061±.002 dia.
Dimensions of tape reel
12±0.1
.472±.004
2±0.1
.079±.004
2±0.5
.079±.020
1.55±0.1 dia.
.061±.004 dia.
21±0.8
.827±.031
13.4±2
.528±.079
(1) When picked from 1/2-pin side: Part No. APS❍❍❍1SX (Shown above)
(2) When picked from 3/4/5-pin side: Part No. APS❍❍❍1SZ
–10–
2±0.5
.079±.020
ASCTB387E 201703-T