Kemet A700X337M004ATE015 Aluminum organic capacitor Datasheet

ALUMINUM ORGANIC CAPACITORS
Performance Characteristics
4. Voltage Ratings
• 2 - 10 VDC Rated Voltage
This is the maximum peak DC operating voltage
from -55°C to +125°C for continuous duty.
Surge Voltage Ratings
Surge voltage capability is demonstrated by application of 1000 cycles of the relevant voltage at 25°C,
85°C, or 125 °C. The parts are charged through a 33
ohm resistor for 30 seconds and then discharged
through a 33 ohm resistor for 30 seconds for each
cycle.
The AO-CAP offers many advantages including extremely low ESR, high capacitance retention at high operating
frequencies, no dry-out related failure mechanism and
no voltage de-rating up to125°C.
Voltage Ratings • Table 1
Rated
Surge
Voltage
Voltage
-55°C to 125 °C
2V
2.6V
2.5V
3.2V
4V
5.2V
6.3V
8V
8V
10.4V
10V
13V
ELECTRICAL
1. Operating Temperature Range
• -55°C to +125°C
No derating with temperature is required.
2. Non-Operating Temperature Range
• -55°C to 125°C
3. Capacitance and Tolerance
• 22µF to 470µF
• ±20% Tolerance
Capacitance is measured at 120 Hz, up to 1.0 volt
rms maximum and up to 2.5V DC maximum. DC
bias causes only a small reduction in capacitance,
up to about 2% when full rated voltage is applied.
DC bias is not commonly used for room temperature
measurements but is more commonly used when
measuring at temperature extremes.
Capacitance does decrease with increasing frequency, but not nearly as much or as quickly as
standard tantalums. Figure 1 compares the frequency induced cap roll-off between the AO-CAP and traditional MnO2 types. Capacitance also increases
with increasing temperature. See Section 12 for temperature coefficients.
5. Reverse Voltage Rating & Polarity
Aluminum polymer capacitors are polar devices and
may be permanently damaged or destroyed if connected in the wrong polarity. The positive terminal is
identified by a laser-marked stripe. These capacitors
will withstand a certain degree of transient voltage
reversal for short periods as shown in the following
table. Please note that these parts may not be operated continuously in reverse, even within these limits.
Table 2
Temperature
25°C
55°C
85°C
125°C
Permissible Transient Reverse Voltage
60% of Rated Voltage
50% of Rated Voltage
40% of Rated Voltage
30% of Rated Voltage
6. DC Leakage Current
Because of the high conductivity of the polymer, the
AO-CAP family has higher leakage currents than traditional MnO2 type Tantalum caps. The DC Leakage
limits at 25°C are calculated as 0.06 x C x V, (where
C is cap in µF and V is rated voltage in Volts) for
part types with rated voltage ≤ 4V, and equals 0.04 x
C x V, for voltages > 4V. Limits for all part numbers
are listed in the ratings tables.
Figure 1.
58
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
Aluminum Organic Capacitors
Introduction
KEMET entered the world of aluminum capacitors with
the introduction of the AO-CAP, designated the A700
Series, which has been targeted for power management
applications. The structure of the AO-CAP uses aluminum as the anode material, aluminum oxide as the
dielectric, and a conductive organic polymer for its
counter-electrode material. The A700 series is 100%
screened for all electrical parameters: Capacitance @
120Hz, Dissipation Factor (DF) @ 120 Hz, ESR @ 100
kHz, and DC Leakage.
ALUMINUM ORGANIC CAPACITORS
Performance Characteristics
DC Leakage Current does increase with temperature. The limits for 85°C @ Rated Voltage and
125°C are both 2 times the 25°C limit.
7. Dissipation Factor (DF)
Refer to part number tables for maximum DF limits.
Dissipation factor is measured at 120 Hz, up to 1.0
volt rms maximum. Dissipation factor is the ratio of
the equivalent series resistance (ESR) to the capacitive reactance, (Xc) and is usually expressed as a
percentage. It is directly proportional to both capacitance and frequency. Dissipation factor loses its
importance at higher frequencies, (above about 1
kHz), where impedance (Z) and equivalent series
resistance (ESR) are the normal parameters of concern.
R
DF = X = 2πfCR
c
Where:
DF = Dissipation Factor
R = Equivalent Series Resistance (Ohms)
Xc = Capacitive Reactance(Ohms)
f
= Frequency (Hertz)
C = Capacitance (Farads)
DF is also referred to as tan δ or "loss tangent."
The "Quality Factor," "Q", is the reciprocal of DF.
8. Equivalent Series Resistance (ESR) and
Impedance (Z)
The Equivalent Series Resistance (ESR) of the AOCAP is much lower than standard Tantalum caps
because the polymer cathode has much higher conductivity. ESR is not a pure resistance, and it
decreases with increasing frequency.
Total impedance of the capacitor is the vector sum of
capacitive reactance (Xc) and ESR below reso
nance; above resonance total impedance is the vector sum of inductive reactance (XL) and ESR.
ESR
Xc =
1
2πfC
θ
(Ohms)
δ
Where:
f = frequency (Hertz)
C = capacitance (Farad)
Xc
Figure 2a Total Impedance of the Capacitor
Below Resonance
XL = 2πfL (Ohms)
Z
Where:
f = frequency (Hertz)
L = inductance (Henries)
XL
Aluminum Organic Capacitors
DC Leakage Current is the current that flows
through the capacitor dielectric after a five minute
charging period at rated voltage. Leakage is measured at 25°C with full rated voltage applied to the
capacitor through a 1000 ohm resistor in series with
the capacitor.
δ
θ
ESR
Figure 2b Total Impedance of the Capacitor
Above Resonance
To understand the many elements of a capacitor,
see Figure 3.
C
ESL
ESR
RL
Cd
Rd
Figure 3 The Real Capacitor
A capacitor has a complex impedance consisting of
many series and parallel elements, each adding to
the complexity of the measurement system.
ESL - Represents inductance. In most instances it is
significant at the basic measurement frequencies of
120 and 1000 Hz.
ESR - Represents the ohmic resistance in series
with the capacitance. Lead attachment and capacitor
electrodes are contributing sources.
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
59
ALUMINUM ORGANIC CAPACITORS
Performance Characteristics
As frequency increases, Xc continues to decrease
according to its equation. There is unavoidable
inductance as well as resistance in all capacitors,
and at some point in frequency, the reactance ceases to be capacitive and becomes inductive. This frequency is call the self-resonant point.
Figure 4 compares the frequency response of an
AO-CAP to a Tantalum chip. Maximum limits for 100
kHz ESR are listed in the part number tables for
each series.
10. Ripple Current/Voltage
Permissible AC ripple voltage and current are related
to equivalent series resistance (ESR) and power dissipation capability.
Permissible ripple current which may be applied
is limited by two criteria:
a. The resulting voltage across the capacitor with the
summation of DC bias and peak voltage of the
AC portion must not exceed the rated voltage of
the capacitor.
b. The negative peak AC voltage, in combination
with bias voltage, if any, must not exceed the permissible reverse voltage ratings presented in
Section 5.
Actual power dissipated may be calculated from the
following:
P = I 2R
Substituting I = E ; P = E2R
Z
Z2
Where:
I = rms ripple current (Amperes)
E = rms ripple voltage (Volts)
P = power (Watts)
Z = impedance at specified frequency (ohms)
R = ESR(Ohms)
Using P max from Table 3, maximum allowable rms
ripple current or voltage may be determined as follows:
Imax =
Figure 4.
9. AC Power Dissipation
Power dissipation is a function of capacitor size and
materials. Maximum power ratings have been established for all case sizes to prevent overheating. In
actual use, the capacitor's ability to dissipate the
heat generated at any given power level may be
affected by a variety of circuit factors. These include
board density, pad size, heat sinks and air circulation.
Power capability is determined based on a 20°C temperature rise. A higher temperature rise and therefore
higher power capability is allowable as long as the
ambient temperature plus temperature rise due to ripple current does not exceed the rated temperature of
the part.
Case Code
KEMET
EIA
Maximum Power Dissipation mWatts
@ +25°C with 20° Temperature Rise
V
7343-20
270
D
7343-31
250
X
7343-43
225
Pmax
ESR
Emax = Z
R
Where:
Imax = Maximum rupple current (ARMS)
Pmax = Maximum Power @ allowable ∆T normally
+20°C
Emax = Maximum ripple voltage (VRMS)
Refer to part number listings for permittable Arms
limits.
Table 3 - AO Capacitor Power Dissipation Ratings
60
Pmax
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
Aluminum Organic Capacitors
RL - Capacitor Leakage Resistance. Typically it can
be 35 K to 2.5 MOhms depending on voltage capacitance. It can exceed 1012 ohms in monolithic
ceramics and in film capacitors.
Rd - The dielectric loss contributed by dielectric
absorption and molecular polarization. It becomes
very significant in high frequency measurements and
applications. Its value varies with frequency.
Cd - The inherent dielectric absorption of the solid
aluminum capacitor.
ALUMINUM ORGANIC CAPACITORS
Performance Characteristics
11. Temperature Stability
Mounted capacitors withstand extreme temperature
testing at a succession or continuous steps at
+25°C, -55°C, +25°C, +85°C, +125°C, +25°C in that
order. Capacitors are allowed to stabilize at each
temperature before measurement. Cap, DF, and
DCL are measured at each temperature; except DC
Leakage is not measured at -55°C.
Step
Temp
∆Cap
DCL
DF
1
25°C
Specified
Tolerance
Catalog
Limit
Catalog
Limit
2
-55°C
15% of
initial value
N/A
Catalog
Limit
3
+25°C
5% of
initial value
Catalog
Limit
Catalog
Limit
4
+85°C
15% of
initial value
2X Catalog
Limit
Catalog
Limit
5
+125°C
20% of
initial value
2X Catalog
Limit
Catalog
Limit
6
+25°C
5% of
initial value
Catalog
Limit
Catalog
Limit
Table 4 - Acceptable limits are as follows:
12. Standard Life Test
• 85°C, Rated Voltage, 2000 Hours
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR: within initial limit
13. High Temperature Life Test
• 125°C, Rated Voltage, 2000 Hours
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within 1.25 x initial limit
d. ESR: within 2 x initial limit
14. Storage Life Test
• 125°C, O VDC, 2000 Hours
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within 1.25 x initial limit
d. ESR: within 2 x initial limit
15. Thermal Shock
• Mil-Std-202, Method 107, Condition B
Minimum temperature is -55°C
Maximum temperature is +125°C
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR: within 2 x initial limit
16. Moisture Sensitivity Level (MSL)
• J-Std-020
a. Capacitance: within ±30% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR: within 2 x initial limit
Meets MSL 3 requirements for SnPb assembly.
17. Load Humidity
• 85°C, 85% RH, Rated Voltage, 500 Hours
a. Capacitance: within +30/-5% of initial value
b. DF: within initial limit
c. DC Leakage: within 5 x initial limit
d. ESR: within 2 x initial limit
18. ESD
• Polymer Aluminum capacitors are not sensitive to Electro-Static Discharge (ESD).
19. Failure Mechanism and Reliability
The normal failure mechanism is dielectric break
down. Dielectric failure can result in high DC
Leakage current and may proceed to the level of a
short circuit. With sufficient time to charge, healing
may occur by one of two potential mechanisms. The
polymer adjacent to the dielectric fault site may overheat and vaporize, disconnecting the fault site from
the circuit. The polymer may also oxidize into a more
resistive material that caps the defect site in the
dielectric and reduces the flow of current.
Aluminum Organic Capacitors
ENVIRONMENTAL
Capacitor failure may be induced by exceeding the
rated conditions of forward DC voltage, reverse DC
voltage, surge current, power dissipation or temperature. Excessive environmental stress, such as prolonged or high temperature reflow processes may
also trigger dielectric failure.
20. Resistance to Solvents
• Mil-Std 202, Method 215
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR: within initial limit
e. Physical: no degradation of case, terminals or
marking
21. Fungus
• Mil-Std-810, Method 508
22. Flammability
• UL94 VO Classification
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
61
ALUMINUM ORGANIC CAPACITORS
Performance Characteristics
24. Solderability
• Mil-Std-202, Method 208
• ANSI/J-Std-002, Test B
25. Vibration
• Mil-Std-202, Method 204, Condition D, 10 Hz to
2,000 Hz, 20G Peak
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR: within initial limit
26. Shock
• Mil-Std-202, Method 213, Condition I, 100 G
Peak
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR: within initial limit
27. Terminal Strength
• Pull Force
• One Pound (454 grams), 30 Seconds
• Tensile Force
• Four Pounds (1.8 kilograms), 60 Seconds
Post Test Performance:
a. Capacitance: within ±5% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR within initial limit
28. Handling
Automatic handling of encapsulated components is
enhanced by the molded case which provides compatibility with all types of high speed pick and place
equipment. Manual handling of these devices presents no unique problems. Care should be taken with
your fingers, however, to avoid touching the soldercoated terminations as body oils, acids and salts will
degrade the solderability of these terminations.
Finger cots should be used whenever manually handling all solderable surfaces.
29. Termination Coating
The standard finish coating is 100% Sn solder
(Tin-solder coated) with nickel (Ni) underplating.
30. Recommended Mounting Pad Geometries
Proper mounting pad geometries are essential for
successful solder connections. These dimensions
are highly process sensitive and should be designed
to maximize the integrity of the solder joint, and to
minimize component rework due to unacceptable
solder joints.
Figure 5 illustrates pad geometry. The table provides
recommended pad dimensions for reflow soldering
techniques. These dimensions are intended to be a
starting point for circuit board designers, to be fine
tuned, if necessary, based upon the peculiarities of
the soldering process and/or circuit board design.
Contact KEMET for Engineering Bulletin Number
F-2100 entitled "Surface Mount Mounting Pad
Dimensions and Considerations" for further details
on this subject or visit our website at
www.kemet.com.
•
Shear Force
Table 5 Maximum Shear Loads
Case Code
KEMET
EIA
V
7343-20
D
7343-31
X
7343-43
Maximum Shear Loads
Kilograms
Pounds
5.0
11.0
5.0
11.0
5.0
11.0
C
Figure 5
Grid
Placement
Courtyard
X
G
Y
Z
62
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
Aluminum Organic Capacitors
23. Resistance to Soldering Heat
• Maximum Reflow
+245 ±5°C, 10 seconds
• Typical Reflow
+230 ±5°C, 30 seconds
Post Test Performance:
a. Capacitance: within ±10% of initial value
b. DF: within initial limit
c. DC Leakage: within initial limit
d. ESR: within initial limit
ALUMINUM ORGANIC CAPACITORS
Performance Characteristics
D/7343-31, V/7343-20
X/7343-43
Pad Dimensions
Z
G
X
Y (Ref)
C (Ref)
8.90
3.80
2.70
2.55
6.35
Table 6 - Land Pattern Dimensions for Reflow
Solder
31. Soldering
The A700 - AO-CAP family has been designed for
reflow solder processes, or for wave soldering. The
solder-coated terminations have excellent wetting
characteristics for high integrity solder fillets.
Preheating of these components is recommended to
avoid extreme thermal stress. Figure 6 represents
the recommended maximum solder temperature/
time combinations for these devices.
Hand-soldering should be avoided. However, if necessary it should be performed with care due to the
difficulty in process control. Care should be taken to
avoid contact of the soldering iron to the molded
case. The iron should be used to heat the solder
pad, applying solder between the pad and the termination, until reflow occurs. The iron should be
removed. "Wiping" the edges of a chip and heating
the top surface is not recommended.
AO capacitors should be stored in normal working
environments. While the chips themselves are quite
robust in other environments, solderability will be
degraded by exposure to high temperatures, high
humidity, corrosive atmospheres, and long term storage. In addition, packaging materials will be degraded by high temperature (reels may soften or warp,
and tape peel force may increase). KEMET recommends that maximum storage temperature not
exceed 40 degrees C, and the maximum storage
humidity not to exceed 60% relative humidity. In
addition, temperature fluctuations should be minimized to avoid condensation on the parts, and
atmospheres should be free of chlorine and sulfur
bearing compounds. For optimized solderability, chip
stock should be used promptly, preferably within 1.5
years of receipt.
Sn-Pb
Sn-Pb Profile
300
Temperature (°C)
34. Storage Environment
AO capacitors are shipped in moisture barrier bags
with a desiccant and mositure indicator card. This
series is classified as MSL3 (Moisture Sensitivity
Level 3). Upon opening the moisture barrier bag,
parts should be mounted within 7 days to prevent
mositure absorption and outgassing. If the 7 day
window is exceeded, the parts can be dryed per the
instructions on the bag (168 hours at 40 ± 5°C).
Aluminum Organic Capacitors
KEMET/EIA Size
Code
Tape & Reel Packaging
5 Sec.
250
Case Codes
200
150
45 Sec.
45 Sec.
KEMET
100
90 Sec.
EIA
50
Tape & Reel Dimensions
Tape
Width
mm
Pitch
mm ± 0.1
Part
95 Sec.
0
0
50
60 Sec.
100
150
200
250
300
Time (Seconds)
Figure 6 Sn-Pb Profile measured on the surface
of the component
* Contact KEMET for the latest A700 Pb-free soldering recommendations.
32. Washing
Standard washing techniques and solvents are compatible with all KEMET surface mount aluminum
capacitors. Solvents such as Freon TMC and TMS,
Trichlorethane, methylene chloride, prelate, and isopropyl alcohol are not harmful to these components.
Please note that we are not endorsing the use of
banned or restricted solvents. We are simply stating
that they would not be harmful to the components.
If ultrasonic agitation is utilized in the cleaning
process, care should be taken to minimize energy
levels and exposure times to avoid damage to the
terminations.
KEMET AO-CAPS are also compatible with newer
aqueous and semi-aqueous processes.
33. Encapsulations
Under normal circumstances, potting or encapsulation of KEMET aluminum chips is not required.
Reel Quantity
Spro- 180mm 330mm
cket (7” dia.) (13” dia.)
V
7343-20 12 ± 0.3
8
4
1000
3000
D
7343-31 12 ± 0.3
8
4
500
2500
X
7343-43 12 ± 0.3
8
4
500
2000
Component Marking
Rated
Voltage
476
6K
424
Polarity (+)
Indicator
Picofarad
Code
KEMET ID
1st Digit = year
2nd & 3rd digits =
Week
Aluminum Component Weights
Series
Case Size
Typical Weight
(mg)
A700
A700
A700
V/7343-20
D/7343-31
X/7343-43
120
190
260
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
63
ALUMINUM ORGANIC CAPACITORS
A700 Series
APPLICATIONS
• Input/Output Filters for voltage regulators, converters, and SMPS
• Battery Decoupling (portable, handheld electronics)
• Power Decoupling (Procesor, Transmitter circuits)
• Bulk Capacitor Requirements
FEATURES
•
•
•
•
•
•
•
•
•
Polymer Cathode Technology
Extremely Low ESR
High Frequency Capacitance Retention
Non-ignition Failure Mode
Capacitance: 22 to 470 µF
Self-healing Mechanism
-55° to +125°C Capability
No temperature voltage Derating Up To 125°C
Robust to Surface Mount Process
•
•
•
•
•
•
•
•
100% Accelerated Steady State Aging
Pb Free and RoHS Compliant
Solid-state Technology
Molded Case with Wraparound Termination
Voltage: 2 to 10V
No Reformation Required
EIA Standard Case Size
No Dry-out Related Failure Mechanism
OUTLINE DRAWING
Side View
End View
Bottom View
Aluminum Organic Capacitors
W
F
H
K
S
L
S
DIMENSIONS - MILLIMETERS
Case
KEMET
V
D
X
Size
EIA
7343-20
7343-31
7343-43
L
7.3 ± 0.3
7.3 ± 0.3
7.3 ± 0.3
W
4.3 ± 0.3
4.3 ± 0.3
4.3 ± 0.3
H
1.9 ± 0.1
2.8 ± 0.3
4.0 ± 0.3
K Min.
0.9
1.3
2.1
F ±0.1
2.4
2.4
2.4
S ±0.2
1.3
1.3
1.3
T
E018
Note that glue pad shape may differ at KEMET’s discretion.
A700 ORDERING INFORMATION
A
700
V
476
M
006
A
Aluminum
Series
700 Chip
Case Size
V,D,X
Capacitance Picofarad Code
First two digits represent
significant figures. Third digit
specifies number of zeros.
64
ESR
Lead Material
T = 100% Tin (Sn) Plated
Failure Rate Level
A = Not Applicable
Voltage
As Shown
Capacitance Tolerance
M = ±20%
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
ALUMINUM ORGANIC CAPACITORS
A700 Series
A700 RATINGS & PART NUMBER REFERENCE
Cap
µF
DCL
@VR
DF @
120 Hz
ESR
100 kHz
(mΩ)
Ripple Current
(Arms) @ 100kHz
w/ΔT=+20°C @
-55°C to 125°C
KEMET Part Number
Case Size
A700V107M002ATE018
A700V107M002ATE025
A700V107M002ATE028
A700V127M002ATE018
A700V127M002ATE025
A700V127M002ATE028
A700V157M002ATE009
A700V157M002ATE018
A700V157M002ATE025
A700V157M002ATE028
A700D187M002ATE015
A700D187M002ATE018
A700V227M002ATE009
A700D227M002ATE015
A700D227M002ATE018
A700X277M002ATE010
A700X277M002ATE012
A700X277M002ATE015
A700D337M002ATE007
A700X337M002ATE010
A700X337M002ATE015
A700X397M002ATE010
A700X397M002ATE015
A700X477M002ATE010
A700X477M002ATE015
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
D/7343-31
D/7343-31
V/7343-20
D/7343-31
D/7343-31
X/7343-43
X/7343-43
X/7343-43
D/7343-31
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
100.0
12.0 µA
100.0
12.0 µA
100.0
12.0 µA
120.0
14.4 µA
120.0
14.4 µA
120.0
14.4 µA
150.0
18.0 µA
150.0
18.0 µA
150.0
18.0 µA
150.0
18.0 µA
180.0
21.6 µA
180.0
21.6 µA
220.0
26.4µA
220.0
26.4 µA
220.0
26.4 µA
270.0
32.4 µA
270.0
32.4µA
270.0
32.4 µA
330.0
39.6µA
330.0
39.6 µA
330.0
39.6 µA
390.0
46.8 µA
390.0
46.8 µA
470.0
56.4 µA
470.0
56.4 µA
2.5 Volt Rating @ 125°C
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
18
25
28
18
25
28
9
18
25
28
15
18
9
15
18
10
12
15
7
10
15
10
15
10
15
3.9
3.3
3.1
3.9
3.3
3.1
5.4
3.9
3.3
3.1
4.1
3.7
5.5
4.1
3.7
4.7
4.3
3.9
6.0
4.7
3.9
4.7
3.9
4.7
3.9
A700V826M2R5ATE018
A700V826M2R5ATE025
A700V826M2R5ATE028
A700D157M2R5ATE015
A700D157M2R5ATE018
A700D187M2R5ATE015
A700D187M2R5ATE018
A700X227M2R5ATE010
A700X227M2R5ATE015
A700X337M2R5ATE010
A700X337M2R5ATE015
V/7343-20
V/7343-20
V/7343-20
D/7343-31
D/7343-31
D/7343-31
D/7343-31
X/7343-43
X/7343-43
X/7343-43
X/7343-43
82.0
12.3 µA
82.0
12.3 µA
82.0
12.3 µA
150.0
22.5 µA
150.0
22.5 µA
180.0
27.0 µA
180.0
27.0 µA
220.0
33.0 µA
220.0
33.0 µA
330.0
49.5 µA
330.0
49.5 µA
4 Volt Rating @ 125°C
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
18
25
28
15
18
15
18
10
15
10
15
3.9
3.3
3.1
4.1
3.7
4.1
3.7
4.7
3.9
4.7
3.9
A700V826M004ATE018
A700V826M004ATE025
A700V826M004ATE028
A700D127M004ATE015
A700D127M004ATE018
A700D157M004ATE015
A700D157M004ATE018
A700D187M004ATE015
A700D187M004ATE018
A700X187M004ATE010
A700X187M004ATE015
A700D227M004ATE009
A700X227M004ATE009
A700X227M004ATE010
A700X227M004ATE015
A700X277M004ATE010
A700X277M004ATE015
A700X337M004ATE010
A700X337M004ATE015
V/7343-20
V/7343-20
V/7343-20
D/7343-31
D/7343-31
D/7343-31
D/7343-31
D/7343-31
D/7343-31
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
18
25
28
15
18
15
18
15
18
10
15
9
9
10
15
10
15
10
15
3.9
3.3
3.1
4.1
3.7
4.1
3.7
4.1
3.7
4.7
3.9
5.3
5.3
4.7
3.9
4.7
3.9
4.7
3.9
82.0
82.0
82.0
120.0
120.0
150.0
150.0
180.0
180.0
180.0
180.0
220.0
220.0
220.0
220.0
270.0
270.0
330.0
330.0
19.7 µA
19.7 µA
19.7 µA
28.8 µA
28.8 µA
36.0 µA
36.0 µA
43.2 µA
43.2 µA
43.2 µA
43.2µA
52.8 µA
52.8 µA
52.8 µA
52.8 µA
64.8 µA
64.8 µA
79.2 µA
79.2 µA
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
Aluminum Organic Capacitors
2 Volt Rating @ 125°C
65
ALUMINUM ORGANIC CAPACITORS
A700 Series
A700 RATINGS & PART NUMBER REFERENCE
DF @
120 Hz
ESR
100 kHz
(mΩ)
Ripple Current
(Arms) @ 100kHz
w/ΔT=+20°C @
-55°C to 125°C
22.0
5.5 µA
22.0
5.5 µA
33.0
8.3 µA
33.0
8.3 µA
33.0
8.3 µA
47.0
11.8 µA
47.0
11.8 µA
47.0
11.8 µA
56.0
14.1 µA
56.0
14.1 µA
56.0
14.1 µA
68.0
17.1 µA
68.0
17.1 µA
68.0
17.1 µA
82.0
20.7 µA
82.0
20.7 µA
82.0
20.7 µA
100.0
25.2 µA
100.0
25.2 µA
120.0
30.2 µA
120.0
30.2 µA
120.0
30.2 µA
150.0
37.8 µA
150.0
37.8µA
150.0
37.8 µA
180.0
45.4 µA
180.0
45.4 µA
220.0
55.4 µA
8 Volt Rating @ 125°C
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
28
45
18
25
28
18
25
28
18
25
28
18
25
28
18
25
28
15
18
12
15
18
10
12
15
10
15
15
3.1
2.4
3.9
3.3
3.1
3.9
3.3
3.1
3.9
3.3
3.1
3.9
3.3
3.1
3.9
3.3
3.1
4.1
3.7
4.6
4.1
3.7
4.7
4.3
3.9
4.7
3.9
3.9
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
D/7343-31
D/7343-31
D/7343-31
D/7343-31
X/7343-43
X/7343-43
X/7343-43
22.0
7.0 µA
22.0
7.0 µA
33.0
10.6 µA
33.0
10.6 µA
33.0
10.6 µA
56.0
17.9 µA
56.0
17.9 µA
68.0
21.8 µA
68.0
21.8 µA
100.0
32.0 µA
100.0
32.0 µA
100.0
32.0 µA
10 Volt Rating @ 125°C
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
28
45
18
25
28
15
18
15
18
10
12
15
3.1
2.4
3.9
3.3
3.1
4.1
3.7
4.1
3.7
4.7
4.3
3.9
A700V226M010ATE028
A700V336M010ATE018
A700V336M010ATE025
A700V336M010ATE028
A700D566M010ATE015
A700D566M010ATE018
A700D686M010ATE015
A700D686M010ATE018
A700X107M010ATE010
A700X107M010ATE015
A700X127M010ATE010
A700X127M010ATE015
A700X157M010ATE010
A700X157M010ATE015
V/7343-20
V/7343-20
V/7343-20
V/7343-20
D/7343-31
D/7343-31
D/7343-31
D/7343-31
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
22.0
8.8 µA
33.0
13.2 µA
33.0
13.2 µA
33.0
13.2µA
56.0
22.4 µA
56.0
22.4 µA
68.0
27.2 µA
68.0
27.2 µA
100.0
40.0 µA
100.0
40.0 µA
120.0
48.0 µA
120.0
48.0 µA
150.0
60.0 µA
150.0
60.0 µA
12.5 Volt Rating @ 125°C
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
6%
28
18
25
28
15
18
15
18
10
15
10
15
10
15
3.1
3.9
3.3
3.1
4.1
3.7
4.1
3.7
4.7
3.9
4.7
3.9
4.7
3.9
A700V106M12RATE060
A700V156M12RATE040
A700V226M12RATE030
V/7343-20
V/7343-20
V/7343-20
10.0
5.0 µA
15.0
7.5 µA
22.0
11.0 µA
16 Volt Rating @ 125°C
6%
6%
6%
60
40
30
2.1
2.6
3.0
A700V685M016ATE070
A700V825M016ATE070
V/7343-20
V/7343-20
6%
6%
70
70
1.9
2.4
KEMET Part Number
Case Size
A700V226M006ATE028
A700V226M006ATE045
A700V336M006ATE018
A700V336M006ATE025
A700V336M006ATE028
A700V476M006ATE018
A700V476M006ATE025
A700V476M006ATE028
A700V566M006ATE018
A700V566M006ATE025
A700V566M006ATE028
A700V686M006ATE018
A700V686M006ATE025
A700V686M006ATE028
A700V826M006ATE018
A700V826M006ATE025
A700V826M006ATE028
A700D107M006ATE015
A700D107M006ATE018
A700D127M006ATE012
A700D127M006ATE015
A700D127M006ATE018
A700X157M006ATE010
A700X157M006ATE012
A700X157M006ATE015
A700X187M006ATE010
A700X187M006ATE015
A700X227M006ATE015
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
V/7343-20
D/7343-31
D/7343-31
D/7343-31
D/7343-31
D/7343-31
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
X/7343-43
A700V226M008ATE028
A700V226M008ATE045
A700V336M008ATE018
A700V336M008ATE025
A700V336M008ATE028
A700D566M008ATE015
A700D566M008ATE018
A700D686M008ATE015
A700D686M008ATE018
A700X107M008ATE010
A700X107M008ATE012
A700X107M008ATE015
Cap
µF
DCL
@VR
66
6.8
8.2
4.3 µA
5.2 µA
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
Aluminum Organic Capacitors
6.3 Volt Rating @ 125°C
TANTALUM AND ALUMINUM CHIP CAPACITORS
Packaging Information
Tape & Reel Packaging
KEMET’s Molded Tantalum and Aluminum Chip
Capacitor families are packaged in 8 mm and 12 mm plastic
tape on 7" and 13" reels, in accordance with EIA Standard
481-1: Taping of Surface Mount Components for Automatic
Handling. This packaging system is compatible with all tape
fed automatic pick and place systems.
Right Hand
Orientation
Only
(+)
Embossed Carrier
(–)
Embossment
8mm
±.30
8mm
(0.315")
(.315or±.012")
or
12mm
(0.472")
12mm
±.30
(.472 ±.012")
Top Tape Thickness
.10mm (.004") Max Thickness
178mm
(7.00")
180mm
(7.0")
oror
330mm
(13.00")
330mm
(13.0")
Labeling: Bar code labeling (standard or custom) shall be on the side of the reel opposite the sprocket holes.
Refer to EIA-556.
Case Code
KEMET
EIA
R
2012-12
S
3216-12
T
3528-12
U
6032-15
W
7343-15
V
7343-20
A
3216-18
B
3528-21
C
6032-28
D
7343-31
Y
7343-40
X
7343-43
E
7260-38
Tape
Width-mm
8
8
8
12
12
12
8
8
12
12
12
12
12
7" Reel*
2,500
2,500
2,500
1,000
1,000
1,000
2,000
2,000
500
500
500
500
500
13" Reel*
10,000
10,000
10,000
5,000
3,000
3,000
9,000
8,000
3,000
2,500
2,000
2,000
2,000
* No c-spec required for 7" reel packaging. C-7280 required for 13" reel packaging.
* Standard reel packaging is not mandatory.
* Bulk packaging also available using C-7610.
92
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
Packaging
QUANTITIES PACKAGED PER REEL
TANTALUM, CERAMIC AND
ALUMINUM CHIP CAPACITORS
Packaging Information
Performance Notes
1. Cover Tape Break Force: 1.0 Kg Minimum.
2. Cover Tape Peel Strength: The total peel strength of the cover tape from the carrier tape shall be:
Tape Width
Peel Strength
8 mm
0.1 Newton to 1.0 Newton (10g to 100g)
12 mm
0.1 Newton to 1.3 Newton (10g to 130g)
The direction of the pull shall be opposite the direction of the carrier tape travel. The pull angle of the carrier
tape shall be 165 to 180 from the plane of the carrier tape. During peeling, the carrier and/or cover tape
shall be pulled at a velocity of 300 ±10 mm/minute.
3. Reel Sizes: Molded tantalum capacitors are available on either 180 mm (7") reels (standard) or 330 mm (13")
reels (with C-7280). Note that 13” reels are preferred.
4. Labeling: Bar code labeling (standard or custom) shall be on the side of the reel opposite the sprocket holes.
Refer to EIA-556.
Embossed Carrier Tape Configuration: Figure 1
Table 1 — EMBOSSED TAPE DIMENSIONS (Metric will govern)
Constant Dimensions — Millimeters (Inches)
Tape Size
8 mm
and
12 mm
D0
E
1.5
1.75 ±0.10
+0.10 -0.0
(0.059
(0.069 ±0.004)
+0.004, -0.0)
P0
P2
T Max
T1 Max
4.0 ±0.10
2.0 ±0.05
0.600
0.100
(0.157 ±0.004)
(0.079 ±0.002)
(0.024)
(0.004)
Variable Dimensions — Millimeters (Inches)
Tape Size
Pitch
B1 Max.
Note 1
D1 Min.
Note 2
F
P1
R Min.
Note 3
T2 Max
W
8 mm
Single
(4 mm)
4.4
1.0
3.5 ±0.05
4.0 ±0.10
25.0
2.5
8.0 ±0.30
(.315 ±0.012)
12 mm
Double
(8 mm)
(0.173)
(0.039) (0.138 ±0.002)
(0.157 ±0.004) (0.984)
(0.098)
8.2
(0.323)
1.5
5.5 ±0.05
(0.059) (0.217 ±0.002)
8.0 ±0.10
30.0
(0.315 ±0.004) (1.181)
4.6
12.0 ±0.30
(0.181) (0.472 ±0.012)
A0B0K0
Note 4
NOTES
1. B1 dimension is a reference dimension for tape feeder clearance only.
2. The embossment hole location shall be measured from the sprocket hole controlling the location of the embossment. Dimensions of
embossment location and hole location shall be applied independent of each other.
3. Tape with components shall pass around radius “R” without damage (see sketch A). The minimum trailer length (Fig. 2) may require
additional length to provide R min. for 12 mm embossed tape for reels with hub diameters approaching N min. (Table 2)
4. The cavity defined by A0, B0, and K0 shall be configured to surround the part with sufficient clearance such that the chip does not protrude beyond the sealing plane of the cover tape, the chip can be removed from the cavity in a vertical direction without mechanical
restriction, rotation of the chip is limited to 20 degrees maximum in all 3 planes, and lateral movement of the chip is restricted to 0.5 mm
maximum in the pocket (not applicable to vertical clearance.)
94
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
TANTALUM, CERAMIC AND
ALUMINUM CHIP CAPACITORS
Packaging Information
Embossed Carrier Tape Configuration (cont.)
20°
Sketch D: Tape Camber (Top View)
1mm (0.039) Max.
1mm (0.039) Max.
250mm (9.843)
Allowable camber to be 1 mm/250 mm.
400mm (15.75) Min.
Figure 2:
Tape Leader
& Trailer
Dimensions
(Metric
Dimensions
Will Govern)
Packaging
Figure 3: Reel Dimensions (Metric Dimensions will govern)
Table 2 – REEL DIMENSIONS (Metric will govern)
Tape Size
8 mm
A Max
330.0
(12.992)
B* Min
1.5
(0.059)
C
13.0 ± 0.20
(0.512 ± 0.008)
D* Min
20.2
(0.795)
12 mm
330.0
(12.992)
1.5
(0.059)
13.0 ± 0.20
(0.512 ± 0.008)
20.2
(0.795)
N Min
50.0
(1.969)
See
Note 3
Table 1
W1
8.4
+1.5, -0.0
(0.331
+0.059, -0.0)
12.4
+2.0, -0.0
(0.488
+0.078, -0.0)
W2 Max
14.4
(0.567)
18.4
(0.724)
©KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300
W3
7.9 Min
(0.311)
10.9 Max
(0.429)
11.9 Min
(0.469)
15.4 Max
(0.606)
95
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