ETC V5.5MLA1206H

[ /Title
(ML
Series)
/Subject
(Multilayer
Surface
Mount
Transient
Voltage
Surge
Suppressors)
/Autho
r ()
/Keywords
(TVS,
Transient
Suppression,
Protection,
Automotive,
Load
Dump,
Alternator
Field
Decay,
ML Series
Data Sheet
Multilayer Surface Mount Transient
Voltage Surge Suppressors
July 1999
File Number
2461.10
Features
• Leadless 0603, 0805, 1206 and 1210 Chip Sizes
The ML Series is a family of Transient Voltage Surge
Suppression devices based on the Harris Multilayer
fabrication technology. These components are designed to
suppress a variety of transient events, including those
specified by the IEC or other standards used for
Electromagnetic Compliance (EMC). The ML Series is
typically applied to protect integrated circuits and other
components at the circuit board level.
• Wide Operating Voltage Range VM(DC) = 3.5V to 120V
The wide operating voltage and energy range make the ML
Series suitable for numerous applications on power supply,
control and signal lines.
• No Plastic or Epoxy Packaging Assures Better than 94V-0
Flammability Rating
• Multilayer Ceramic Construction Technology
• -55oC to 125oC Operating Temperature Range
• Rated for Surge Current (8 x 20)
• Rated for Energy (10 x 1000)
• Inherent Bidirectional Clamping
• Standard Low Capacitance Types Available
The ML Series is manufactured from semiconducting
ceramics providing bidirectional voltage clamping and is
supplied in leadless, surface mount form, compatible with
modern reflow and wave soldering procedures.
Harris manufactures other Multilayer Series products. See the
MLE Series data sheet (Harris AnswerFAX, 407-724-7800, Doc
#2463) for ESD applications. See the AUML Series for
automotive applications (AnswerFAX Doc #3387) and the MLN
Quad Array (AnswerFAX Doc #4682).
Applications
• Suppression of Inductive Switching or Other Transient
Events Such as EFT and Surge Voltage at the Circuit
Board Level
• ESD Protection for Components Sensitive to IEC 1000-42, MIL-STD-883C Method 3015.7, and Other Industry
Specifications (See Also the MLE or MLN Series)
• Provides On-Board Transient Voltage Protection for ICs
and Transistors
• Used to Help Achieve Electromagnetic Compliance of End
Products
• Replace Larger Surface Mount TVS Zeners in Many
Applications
Packaging
ML SERIES (LEADLESS CHIP)
5-3
1-800-4-HARRIS or 407-727-9207 | Copyright
© Harris Corporation 1999
ML Series
Absolute Maximum Ratings
For ratings of individual members of a series, see device ratings and specifications table.
Continuous:
Steady State Applied Voltage:
DC Voltage Range (VM(DC)) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
AC Voltage Range (VM(AC)RMS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Transient:
Non-Repetitive Surge Current, 8/20µs Waveform, (ITM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Non-Repetitive Surge Energy, 10/1000µs Waveform, (WTM). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Operating Ambient Temperature Range (TA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Storage Temperature Range (TSTG) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Temperature Coefficient (αV) of Clamping Voltage (VC) at Specified Test Current . . . . . . . . . . . . . . . . .
ML SERIES
UNITS
3.5 to 68
2.5 to 50
V
V
30 to 250
0.1 to 1.2
-55 to 125
-55 to 150
<0.01
A
J
oC
oC
%/oC
Device Ratings and Specifications
MAXIMUM RATINGS (125oC)
SPECIFICATIONS (25oC)
MAXIMUM
CONTINUOUS
WORKING
VOLTAGE
MAXIMUM
NONREPETITIVE
SURGE
CURRENT
(8/20µs)
MAXIMUM
NONREPETITIVE
SURGE
ENERGY
(10/1000µs)
MAXIMUM
CLAMPING
VOLTAGE AT
10A
(OR AS NOTED)
(8/20µs)
VN(DC)
VN(DC)
VM(DC) VM(AC)
ITM
WTM
VC
MIN
MAX
C
NOMINAL VOLTAGE
AT 1mA DC TEST
CURRENT
TYPICAL
CAPACITANCE
AT f = 1MHz
PART
NUMBER
(V)
(V)
(A)
(J)
(V)
(V)
(V)
(pF)
V3.5MLA0603
3.5
2.5
30
0.1
10 at 2A
3.7
7.0
1100
V3.5MLA0805
3.5
2.5
120
0.3
10 at 5A
3.7
7.0
2200
V3.5MLA0805L
3.5
2.5
40
0.1
10 at 2A
3.7
7.0
1200
V3.5MLA1206
3.5
2.5
100
0.3
14
3.7
7.0
6000
V5.5MLA0603
5.5
4.0
30
0.1
15.5 at 2A
7.1
9.3
660
V5.5MLA0805
5.5
4.0
120
0.3
15.5 at 5A
7.1
9.3
1600
V5.5MLA0805L
5.5
4.0
40
0.1
15.5 at 2A
7.1
9.3
860
V5.5MLA1206
5.5
4.0
150
0.4
15.5
7.1
9.3
4500
V9MLA0603
9.0
6.5
30
0.1
23 at 2A
11.0
16.0
420
V9MLA0805L
9.0
6.5
40
0.1
20 at 2A
11
14
450
V12MLA0805L
12
9.0
40
0.1
25 at 2A
14
18.5
350
V14MLA0603
14
10
30
0.1
30 at 2A
15.9
20.3
150
V14MLA0805
14
10
120
0.3
30 at 5A
15.9
20.3
480
V14MLA0805L
14
10
40
0.1
30 at 2A
15.9
20.3
270
V14MLA1206
14
10
150
0.4
30
15.9
20.3
1600
5-4
ML Series
Device Ratings and Specifications
(Continued)
MAXIMUM RATINGS (125oC)
PART
NUMBER
SPECIFICATIONS (25oC)
MAXIMUM
CONTINUOUS
WORKING
VOLTAGE
MAXIMUM
NONREPETITIVE
SURGE
CURRENT
(8/20µs)
MAXIMUM
NONREPETITIVE
SURGE
ENERGY
(10/1000µs)
MAXIMUM
CLAMPING
VOLTAGE AT
10A
(OR AS NOTED)
(8/20µs)
VN(DC)
VN(DC)
VM(DC) VM(AC)
ITM
WTM
VC
MIN
MAX
C
NOMINAL VOLTAGE
AT 1mA DC TEST
CURRENT
TYPICAL
CAPACITANCE
AT f = 1MHz
(V)
(V)
(A)
(J)
(V)
(V)
(V)
(pF)
V18MLA0603
18
14
30
0.1
40 at 2A
22
28.0
125
V18MLA0805
18
14
120
0.3
40 at 5A
22
28.0
450
V18MLA0805L
18
14
40
0.1
40 at 2A
22
28.0
250
V18MLA1206
18
14
150
0.4
40
22
28.0
1100
V18MLA1210
18
14
500
2.5
40
22
28.0
1250
V26MLA0603
26
20
30
0.1
58 at 2A
31
38
90
V26MLA0805
26
20
100
0.3
58 at 5A
29.5
38.5
190
V26MLA0805L
26
20
40
0.1
58 at 2A
29.5
38.5
115
V26MLA1206
26
20
150
0.6
56
29.5
38.5
900
V26MLA1210
26
20
300
1.2
54
29.5
38.5
1000
V30MLA0603
30
25
30
0.1
65 at 2A
37
46
75
V30MLA0805L
30
25
30
0.1
65 at 2A
37
46
80
V30MLA1210
30
25
280
1.2
62
35
43
1575
V30MLA1210L
30
25
220
0.9
62
35
43
1530
V33MLA1206
33
26
180
0.8
72
38
49
550
V42MLA1206
42
30
180
0.8
86
46
60
550
V48MLA1210
48
40
250
1.2
100
54.5
66.5
450
V48MLA1210L
48
40
220
0.9
100
54.5
66.5
430
V56MLA1206
56
40
180
1.0
110
61
77
150
V60MLA1210
60
50
250
1.5
120
67
83
375
V68MLA1206
68
50
180
1.0
130
76
90
150
V85MLA1210
85
67
250
2.5
160
95
115
225
V120MLA1210
120
107
125
2.0
230
135
165
65
NOTES:
1. L suffix is a low capacitance and energy version. Contact Sales for custom capacitance requirements.
2. Typical leakage at 25oC < 25µA, maximum leakage 50µA at VM(DC).
3. Average power dissipation of transients for 0603, 0805, 1206 and 1210 sizes not to exceed 0.05, 0.10W, 0.10W and 0.15W, respectively.
5-5
ML Series
Power Dissipation Ratings
100
PERCENT OF RATED VALUE
When transients occur in rapid succession the average
power dissipation is the energy (watt-seconds) per pulse
times the number of pulses per second. The power so
developed must be within the specifications shown on the
Device Ratings and Characteristics table for the specific
device. Certain parameter ratings must be derated at high
temperatures as shown in Figure 1.
90
80
70
60
50
40
30
20
10
0
-55
50
60
70
80
90
100
110 120
130 140 150
AMBIENT TEMPERATURE (oC)
PERCENT OF PEAK VALUE
FIGURE 1. CURRENT, ENERGY AND POWER DERATING
CURVE
100
90
O1 = VIRTUAL ORIGIN OF WAVE
EXAMPLE:
t = TIME FROM 10% TO 90% OF PEAK FOR AN 8/20µs CURRENT
t1 = VIRTUAL FRONT TIME = 1.25 x t
WAVEFORM:
t2 = VIRTUAL TIME TO HALF VALUE
8µs = t1 = VIRTUAL FRONT
(IMPULSE DURATION)
TIME
20µs = t2 = VIRTUAL TIME TO
HALF VALUE
50
10
O1
t
t1
TIME
t2
FIGURE 2. PEAK PULSE CURRENT TEST WAVEFORM
5-6
ML Series
Maximum Transient V-I Characteristic Curves
100
MAXIMUM CLAMPING VOLTAGE (V)
V30MLA0603
V26MLA0603
V18MLA0603
V14MLA0603
V9MLA0603
10
V5.5MLA0603
V3.5MLA0603
MAXIMUM CLAMP
VOLTAGE
MAXIMUM
LEAKAGE
1
100nA
TA = 25oC
V3.5MLA0603 TO V30MLA0603 VM(AC) RATING
10µA
1µA
100µA
1mA
10mA
100mA
1A
10A
100A
CURRENT (I)
FIGURE 3. V3.5MLA0603 TO V30MLA0603 MAXIMUM V-I CHARACTERISTIC CURVES
100
MAXIMUM CLAMPING VOLTAGE (V)
V26MLA0805
V18MLA0805
V14MLA0805
V5.5MLA0805
10
V3.5MLA0805
MAXIMUM CLAMP
VOLTAGE
MAXIMUM
LEAKAGE
1
100nA
TA = 25oC
V3.5MLA0805 TO V30MLA0805 VM(AC) RATING
1µA
10µA
100µA
1mA
10mA
100mA
1A
10A
CURRENT (I)
FIGURE 4. V3.5MLA0805 TO V26MLA0805 MAXIMUM V-I CHARACTERISTIC CURVES
5-7
100A
1000A
ML Series
Maximum Transient V-I Characteristic Curves
(Continued)
100
MAXIMUM CLAMPING VOLTAGE (V)
V30MLA0805L
V26MLA0805L
V18MLA0805L
V14MLA0805L
V12MLA0805L
V9MLA0805L
10
V5.5MLA0805L
V3.5MLA0805L
MAXIMUM CLAMP
VOLTAGE
MAXIMUM
LEAKAGE
1
100nA
1µA
10µA
100µA
TA = 25oC
V3.5MLA0805L TO V30MLA0805L VM(AC) RATING
1mA
10mA
100mA
1A
10A
100A
1000A
CURRENT (I)
FIGURE 5. V3.5MLA0805L TO V30MLA0805L MAXIMUM V-I CHARACTERISTIC CURVES
MAXIMUM CLAMPING VOLTAGE (V)
1000
TA = 25oC
V3.5MLA1206 TO V68MLA1206 VM(AC) RATING
V68MLA1206
V56MLA1206
V42MLA1206
V33MLA1206
V26MLA1206
V18MLA1206
100
V14MLA1206
V5.5MLA1206
10
V3.5MLA1206
MAXIMUM
LEAKAGE
1
100nA
1µA
10µA
100µA
MAXIMUM CLAMP
VOLTAGE
1mA
10mA
100mA
1A
10A
CURRENT (I)
FIGURE 6. V3.5MLA1206 TO V68MLA1206 MAXIMUM V-I CHARACTERISTIC CURVES
5-8
100A
1000A
ML Series
Maximum Transient V-I Characteristic Curves
MAXIMUM CLAMPING VOLTAGE (V)
1000
(Continued)
TA = 25oC
V18MLA1210 TO V120MLA1210 VM(AC) RATING
V120MLA1210
V85MLA1210
V60MLA1210
MAXIMUM CLAMP
VOLTAGE
MAXIMUM
LEAKAGE
100
V48MLA1210, V48MLA1210L
V30MLA1210, V30MLA1210L
V26MLA1210
V18MLA1210
10
100nA
10µA
1µA
100µA
1mA
10mA
100mA
1A
10A
100A
1000A
CURRENT (I)
FIGURE 7. V18MLA1210 TO V120MLA1210 MAXIMUM V-I CHARACTERISTIC CURVES
Device Characteristics
Speed of Response
At low current levels, the V-I curve of the multilayer transient
voltage suppressor approaches a linear (ohmic) relationship
and shows a temperature dependent affect (Figure 8). At or
below the maximum working voltage, the suppressor is in a
high resistance mode (approaching 106Ω at its maximum
rated working voltage). Leakage currents at maximum rated
voltage are below 50µA, typically 25µA.
The Multilayer Suppressor is a leadless device. Its response
time is not limited by the parasitic lead inductances found in
other surface mount packaging. The response time of the
Zinc Oxide dielectric material is less than 1 nanosecond and
the ML can clamp very fast dV/dT events such as ESD.
Additionally, in “real world” applications, the associated
circuit wiring is often the greatest factor effecting speed of
response. Therefore, transient suppressor placement within
a circuit can be considered important in certain instances.
When clamping transients at and above the 10mA range, the
multilayer suppressor approaches a 1Ω -10Ω characteristic.
Here, the multilayer becomes virtually temperature
independent (Figure 9).
80
VNOM VALUE AT 25oC (%)
SUPPRESSOR VOLTAGE IN PERCENT OF
100
60
50
40
30
20
25
10
10-9
10-8
50
75
100
125oC
10-7
10-6
10-5
10-4
SUPPRESSOR CURRENT (ADC)
10-3
10-2
FIGURE 8. TYPICAL TEMPERATURE DEPENDENCE OF THE CHARACTERISTIC CURVE IN THE LEAKAGE REGION
5-9
ML Series
Energy Absorption/Peak Current Capability
CLAMPING VOLTAGE (V)
100
Energy dissipated within the ML is calculated by multiplying
the clamping voltage, transient current and transient
duration. An important advantage of the multilayer is its
interdigitated electrode construction within the mass of
dielectric material. This results in excellent current
distribution and the peak temperature per energy absorbed
is very low. The matrix of semiconducting grains combine to
absorb and distribute transient energy (heat) (Figure 10).
This dramatically reduces peak temperature, thermal
stresses and enhances device reliability.
V26MLA1206
V5.5MLA1206
10
-60
-40
-20
0
20
40
60
80
100
120
As a measure of the device capability in energy handling and
peak current, the V26MLA1206A part was tested with
multiple pulses at its peak current rating (150A, 8/20µs). At
the end of the test, 10,000 pulses later, the device voltage
characteristics are still well within specification (Figure 11).
140
TEMPERATURE (oC)
FIGURE 9. CLAMPING VOLTAGE OVER TEMPERATURE
(VC AT 10A)
FIRED CERAMIC
DIELECTRIC
METAL END
TERMINATION
METAL
ELECTRODES
METAL END
TERMINATION
DEPLETION
REGION
DEPLETION
REGION
GRAINS
FIGURE 10. MULTILAYER INTERNAL CONSTRUCTION
100
PEAK CURRENT = 150A
8/20µs DURATION, 30s BETWEEN PULSES
VOLTAGE
V26MLA1206
10
0
2000
4000
6000
8000
NUMBER OF PULSES
FIGURE 11. REPETITIVE PULSE CAPABILITY
5-10
10000
12000
ML Series
Soldering Recommendations
300
MAXIMUM WAVE 260oC
250
TEMPERATURE (oC)
The principal techniques used for the soldering of
components in surface mount technology are Infra Red (IR)
Reflow, Vapor Phase Reflow and Wave Soldering. When
wave soldering, the ML suppressor is attached to the
substrate by means of an adhesive. The assembly is then
placed on a conveyor and run through the soldering process.
With IR and Vapor Phase Reflow the device is placed in a
solder paste on the substrate. As the solder paste is heated
it reflows, and solders the unit to the board.
SECOND PREHEAT
100
FIRST PREHEAT
0
0
0.5
1.0
1.5
2.0
2.5
3.0
TIME (MINUTES)
3.5
4.0
4.5
FIGURE 12. WAVE SOLDER PROFILE
250
MAXIMUM
TEMPERATURE 222oC
200
TEMPERATURE (oC)
Once the soldering process has been completed, it is still
necessary to ensure that any further thermal shocks are
avoided. One possible cause of thermal shock is hot printed
circuit boards being removed from the solder process and
subjected to cleaning solvents at room temperature. The
boards must be allowed to cool to less than 50oC before
cleaning.
150
50
With the ML suppressor, the recommended solder is a 62/36/2
(Sn/Pb/Ag), 60/40 (Sn/Pb), or 63/37 (Sn/Pb). Harris also
recommends an RMA solder flux. Wave soldering operation is
the most strenuous of the processes. To avoid the possibility of
generating stresses due to thermal shock, a preheat stage in
the soldering process is recommended, and the peak
temperature of the solder process should be rigidly controlled.
When using a reflow process, care should be taken to
ensure that the ML chip is not subjected to a thermal
gradient steeper than 4 degrees per second; the ideal
gradient being 2 degrees per second. During the soldering
process, preheating to within 100 degrees of the solders
peak temperature is essential to minimize thermal shock.
Examples of the soldering conditions for the ML series of
suppressors are given in the tables below.
200
40-80
SECONDS
ABOVE 183oC
150
RAMP RATE
>50oC/s
100
PREHEAT ZONE
50
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
TIME (MINUTES)
FIGURE 13. VAPOR PHASE SOLDER PROFILE
Termination Options
Harris offers two types of electrode termination finish for the
Multilayer product series:
250
1. Silver/Platinum (standard)
MAXIMUM
TEMPERATURE 222oC
2. Silver/Palladium (optional)
200
TEMPERATURE (oC)
(The ordering information section describes how to
designate them.)
40-80
SECONDS
ABOVE 183oC
150
RAMP RATE
<2oC/s
100
PREHEAT DWELL
PREHEAT ZONE
50
0
0
0.5
1.0
1.5
2.0
2.5
TIME (MINUTES)
3.0
FIGURE 14. REFLOW SOLDER PROFILE
5-11
3.5
4.0
ML Series
Recommended Pad Outline
C
B
NOTE
A
NOTE: Avoid metal runs in this area.
PAD SIZE
FOR 1210
SIZE DEVICE
FOR 1206
SIZE DEVICE
FOR 0805
SIZE DEVICE
FOR 0603
SIZE DEVICE
SYMBOL
IN
MM
IN
MM
IN
MM
IN
MM
A
0.219
5.53
0.203
5.15
0.144
3.65
0.11
2.8
B
0.147
3.73
0.103
2.62
0.084
2.13
0.064
1.62
C
0.073
1.85
0.065
1.65
0.058
1.48
0.044
1.12
Explanation of Terms
Rated DC Voltage (VM(DC))
This is the maximum continuous DC voltage which may be
applied up to the maximum operating temperature of the
device. The rated DC operating voltage (working voltage) is
also used as the reference point for leakage current. This
voltage is always less than the breakdown voltage of the
device.
system. The leakage current drawn at this level is very low,
as specified in the Device Ratings table.
Nominal Voltage (VN(DC))
This is the voltage at which the device changes from the off
(standby state) to the on (clamping state) and enters its
conduction mode of operation. The voltage value is usually
characterized at the 1mA point and has a specified minimum
and maximum voltage range.
Rated AC Voltage (VM(AC)RMS)
Clamping Voltage (VC)
This is the maximum continuous sinusoidal rms voltage
which may be applied. This voltage may be applied at any
temperature up to the maximum operating temperature of
the device.
This is the peak voltage appearing across the suppressor
when measured at conditions of specified pulse current and
specified waveform.
Maximum Non-Repetitive Surge Current (ITM)
This is the capacitance of the device at a specified frequency
(1MHz) and bias (1VP-P).
This is the maximum peak current which may be applied for
an 8/20µs impulse, with rated line voltage also applied,
without causing device failure. The pulse can be applied to
the device in either polarity with the same confidence factor.
See Figure 2 for waveform description.
Maximum Non-Repetitive Surge Energy (WTM)
This is the maximum rated transient energy which may be
dissipated for a single current pulse at a specified impulse
duration (10/1000µs), with the rated DC or RMS voltage
applied, without causing device failure.
Leakage (IL) at Rated DC Voltage
In the nonconducting mode, the device is at a very high
impedance (approaching 106Ω at its maximum rated
voltage) and appears essentially as an open circuit in the
5-12
Capacitance (C)
ML Series
Mechanical Dimensions
E
L
D
W
CHIP SIZE
1210
1206
0805
0603
SYMBOL
IN
MM
IN
MM
IN
MM
IN
MM
D Max.
0.113
2.87
0.071
1.80
0.043
1.1
0.035
0.9
E
0.02 ±0.01
0.50 ±0.25
0.02 ±0.01
0.50 ±0.25
0.01 to 0.029
0.25 to 0.75
0.015 ±0.008
0.4 ±0.2
L
0.125 ±0.012
3.20 ±0.30
0.125 ±0.012
3.20 ±0.03
0.079 ±0.008
2.01 ±0.2
0.063 ±0.006
1.6 ±0.15
W
0.10 ±0.012
2.54 ±0.30
0.06 ±0.011
1.60 ±0.28
0.049 ±0.008
1.25 ±0.2
0.032 ±0.006
0.8 ±0.15
Ordering Information
VXXML TYPES
V
18
ML
X
1206
X
X
X
ML SERIES
DEVICE FAMILY
Harris TVSS Device
PACKING OPTIONS
A: <100 pc Bulk Pak
H: 7in (178mm) Diameter Reel (Note)
T: 13in (330mm) Diameter Reel (Note)
MAXIMUM DC
WORKING VOLTAGE
END TERMINATION OPTION
No Letter: Ag/Pt (Standard)
W: Ag/Pd
MULTILAYER DESIGNATOR
PERFORMANCE DESIGNATOR
A: Standard
E: ESD (See MLE Data Sheet)
N4: Array (See MLN Data Sheet)
DEVICE SIZE:
i.e., 120 mil x 60 mil
NOTE: See quantity table.
CAPACITANCE OPTION
No Letter: Standard
L: Low Capacitance Version
(Where available - see device ratings
for standard versions)
Standard Shipping Quantities
DEVICE SIZE
“13” INCH REEL (“T” OPTION)
“7” INCH REEL (“H” OPTION)
BULK PACK (“A” OPTION)
1210
8,000
2,000
100
1206
10,000
2,500
100
0805
10,000
2,500
100
0603
10,000
2,500
100
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ML Series
Tape and Reel Specifications
• Conforms to EIA - 481, Revision A
• Can be Supplied to IEC Publication 286 - 3
SYMBOL
DESCRIPTION
MILLIMETERS
A0
Width of Cavity
Dependent on Chip Size to Minimize Rotation.
B0
Length of Cavity
Dependent on Chip Size to Minimize Rotation.
K0
Depth of Cavity
Dependent on Chip Size to Minimize Rotation.
W
Width of Tape
F
Distance Between Drive Hole Centers and Cavity Centers
3.5 ±0.5
E
Distance Between Drive Hole Centers and Tape Edge
1.75 ±0.1
P1
Distance Between Cavity Center
4 ±0.1
P2
Axial Distance Between Drive Hole Centers and Cavity Centers
2 ±0.1
P0
Axial Distance Between Drive Hole Centers
4 ±0.1
D0
Drive Hole Diameter
1.55 ±0.05
D1
Diameter of Cavity Piercing
1.05 ±0.05
t1
Embossed Tape Thickness
0.3 Max
t2
Top Tape Thickness
0.1 Max
8 ±0.2
NOTE: Dimensions in millimeters.
t1
D0
P0
P2
E
F
K0
W
B0
t2
D1
P1
A0
PRODUCT
IDENTIFYING
LABEL
PLASTIC CARRIER TAPE
EMBOSSMENT
TOP TAPE
M0
NOMINAL
178mm
OR 330mm
DIA. REEL
All Harris semiconductor products are manufactured, assembled and tested under ISO9000 quality systems certification.
Harris semiconductor products are sold by description only. Harris Semiconductor Communications Division reserves the right to make changes in circuit design and/or
specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Harris
is believed to be accurate and reliable. However, no responsibility is assumed by Harris or its subsidiaries for its use; nor for any infringements of patents or other rights
of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Harris or its subsidiaries.
For information regarding Harris Semiconductor Communications Division and its products, call 1-800-4-HARRIS or see web site http://www.semi.harris.com
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