TESVSP0J106M8R [RENESAS]
CAP,TANTALUM / TA2O5,10UF,6.3VDC,20% -TOL,20% +TOL,-20,20% TC;
| 型号: | TESVSP0J106M8R |
| 厂家: | 
RENESAS TECHNOLOGY CORP |
| 描述: | CAP,TANTALUM / TA2O5,10UF,6.3VDC,20% -TOL,20% +TOL,-20,20% TC 电容器 |
| 文件: | 总16页 (文件大小:83K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Tantalum Capacitors
SVS Series
SVS SERIES
The SVS series is a line-up of high performance ultra-miniaturized tantalum chip capacitors.
The case dimensions are 2.0 mm × 1.25 mm × 1.2 mm as shown below.
FEATURES
• The smallest molded chip tantalum capacitor
• Available up to 10 µF with case dimension of 2.0 mm × 1.25 mm × 1.2 mm (Case Code P)
• Case size of half as small as the EIA standard A case (EIA Case Code: 3216)
APPLICATIONS
• Portable Stereos
• VCR
• Hearing Aids
OUTLINE DRAWINGS AND DIMENSIONS
2.0 ±0.2
1.25 ±0.2
(0.079 ±0.008)
(0.049 ±0.008)
1.2 max
(0.047 max.)
0.5 ±0.2
0.5 ±0.2
0.9 ±0.1
(0.020 ±0.008)
(0.020 ±0.008)
(0.035 ±0.004)
Unit: mm (inch)
Case Code: P (EIA Case Code: 2012)
63
Tantalum Capacitors
SVS Series
PRODUCT LINE-UP AND MARKING CODE
Rated Voltage
Capaci-
(V dc)
2.5
4
6.3
10
16
tance (µF)
0.33
CN
CS
0.47
0.68
1
AW
AA
AE
AJ
CW
JA
JE
JJ
1.5
2.2
3.3
4.7
6.8
GE
GJ
eJ
eN
eS
eW
eA
GN
GS
GW
GA
JN
JS
JW
JA
AN
10
MARKING
up to 6.8
µ
F
10 µF
Polarity + (Anode)
**Production Date Code
(indicated by dots)
J
A
J A
Marking Code
(corresponding to rated
voltage and capacitance)
**Implement date code on trial.
PART NUMBERING SYSTEM
– Bulk –
– Tap and Reel –
TE SVSP0J105M
SVS
P
0J
105
M
8
R
Capacitance Tolerance ±20%
Packing Orientation
(See below)
Same as
Bulk Part
Capacitance Code in pF
First two digits represent significant
figures.
Tape Width 8 mm for P Case
Tape and Reel
TE: Reel Diameter 178 mm (7 inch)
Third dight specifies number
of zeros to follow.
– Packing Orientaion –
R : Orientation
DC Rated Voltage
0E: 2.5 V, 0G: 4 V, 0J: 6.3 V
1A: 10 V, 1C: 16 V
Direction of Feed
Case Size
Tape
Polarity + (Anode)
Polarity + (Anode)
L : Orientation
SVS Series
Direction of Feed
Tape
64
Tantalum Capacitors
SVS Series
PERFORMANCE CHARACTERISTICS
Item
Specification
Test Method
Operating Temperature Range –55 to +125˚C
Rated Voltage
2.5
3.3
1.6
4
6.3
10
13
16
20
10
Vdc
Vdc
Vdc
Temperature: 85˚C
Temperature: 85˚C
Temperature: 125˚C (*1)
Frequency: 120 Hz
Surge Voltage
5.2
2.5
8
4
Category Voltage
Capacitance Range
Capacitance Tolerance
Leakage Current (L.C.)
6.3
0.33 to 10 µF
±20%
0.01 CV (µA) or 0.5 µA whichever is greater
5 min, after rated voltage applied
Frequency: 120 Hz
Tangent of Loss Angle (tan δ) Refer to Standard Ratings
Equivalent Series Resistance
(ESR)
Refer to standard ratings
Frequency: 100 kHz
Surge Voltage Test
∆C/C : ±20%
Temperature: 8.5˚C
tan δ : Initial requirement
L.C. : Initiail requirement
Surge Voltage for 30 sec.
Series Resistance: 1 kΩ
Discharging Voltage for 5 min. 30 sec.
1000 cycles
Characteristics
at High and Low
Temperature
Temp.
∆C/C
tan δ
–55˚C
+85˚C
+20, 0%
Initial
+125˚C
+20, 0%
Initial
Step 1: 20˚C
Step 1: –55˚C
Step 2: –55˚C
Step 3: 20˚C
0, –20%
Initial
Requirement
Requirement
Requirement
Step 4: 85˚C
Step 5: 125˚C
Step 6: 20˚C
× 1.5
× 1.5
L.C.
–
0.1 CV or 5 µA
whichever is
greater
0.125 CV or 6.25
µA whichever
is greater
Rapid Change of Temperature ∆C/C : ±20%
tan δ : Initial Requirement
–55 to +125˚C
5 cycles
L.C. : Initial Requirement
Resistance to Soldering
Heat
∆C/C : ±20%
Fully immersion to solder,
260˚C, 5 sec.
tan δ : Initial Requirement
L.C. : Initial Requirement
Damp Heat, Steady State
Endurance
∆C/C : ±20%
Temperature: 40˚C
90 to 95% RH
500 hours
tan δ : Initial Requirement × 1.5
L.C. : Initial Requirement 500 hour
∆C/C : ±20%
Temperature: 85˚C
Rated Voltage Applied
Temperature: 125˚C
Category Voltage Applied
2000 hours
tan δ : Initial Requirement
L.C. : Initial Requirement × 2
Failure Rate
LEGEND
λ0 = 1%/1000H
CV : Product of Capacitance in µF and Voltage in V
∆C/C : Capacitance Change Ratio
*1: Category voltage at 85˚C or more is calculated by following expression.
UR – UC
UT = UR –
(T – 85)
40
UR : Rated Voltage
UC : Category Voltage at 125˚C
65
Tantalum Capacitors
SVS Series
RATINGS
DC Rated Voltage
@85°C (125°C)
Vdc
Capacitance
@20°C, 120 Hz
µF
Leakage Current
@20°C
tan δ
ESR
Case
Size
Part Number
@20°C, 120 Hz @20°C, 100 kHz
µA Max.
% Max
10
10
20
20
20
10
10
20
20
20
20
10
10
20
20
20
20
20
10
10
20
20
20
10
10
10
20
Ω Max
25
25
20
20
12
25
25
20
12
12
12
25
25
20
13
12
12
12
25
25
25
20
20
40
35
25
25
2.5
2.2
3.3
4.7
6.8
10
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
SVSP0E225M
SVSP0E335M
SVSP0E475M
SVSP0E685M
SVSP0E106M
SVSP0G155M
SVSP0G225M
SVSP0G335M
SVSP0G475M
SVSP0G685M
SVSP0G106M
SVSP0J105M
SVSP0J155M
SVSP0J225M
SVSP0J335M
SVSP0J475M
SVSP0J685M
SVSP0J106M
SVSP1A684M
SVSP1A105M
SVSP1A155M
SVSP1A225M
SVSP1A335M
SVSP1C334M
SVSP1C474M
SVSP1C684M
SVSP1C105M
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.6
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
(1.6)
4
1.5
2.2
3.3
4.7
6.8
10
(2.5)
6.3
(4)
1
1.5
2.2
3.3
4.7
6.8
10
10
0.68
1
(6.3)
1.5
2.2
3.3
0.33
0.47
0.68
1
16
(10)
66
Tantalum Capacitors
SVS Series
CHARACTERISTICS DATA
Characteristics at High and Low Temperature
30
20
30
20
10
10
0
0
–10
–20
–30
–10
–20
–30
0.08
0.08
0.06
0.06
δ
δ
0.04
0.02
0
0.04
0.02
0
0.1
0.1
µ
µ
0.01
0.01
0.001
0.001
20
–55
20
85
125
20
20
–55
20
85
125
20
Temperature (˚C)
2.2 F/2.5 V
Temperature (˚C)
F/6.3 V
µ
1µ
67
Tantalum Capacitors
SVS Series
Resistance to Soldering Heat (immersing for 10 sec. at 260˚C)
15
10
5
15
10
5
0
0
–5
–10
–15
–5
–10
–15
0.08
0.06
0.04
0.02
0
0.08
0.06
0.04
0.02
0
δ
δ
0.1
0.01
0.1
0.01
µ
µ
0.001
0.001
Initial
Final
Initial
Final
2.2
µ
F/2.5 V
1µF/6.3 V
68
Tantalum Capacitors
SVS Series
Damp Heat, Steady State (65˚C, 90 to 95% RH)
15
10
5
15
10
5
0
0
–5
–10
–15
–5
–10
–15
0.08
0.08
0.06
0.06
δ
δ
0.04
0.02
0
0.04
0.02
0
0.1
0.1
µ
µ
0.01
0.01
0.001
Initial
0.001
500 h
F/2.5 V
1000 h
Initial
500 h
1µF/6.3 V
1000 h
2.2
µ
69
Tantalum Capacitors
SVS Series
Endurance (85˚C Rated Voltage × 1.3 Applied)
30
20
30
20
10
10
0
0
–10
–20
–30
–10
–20
–30
0.08
0.08
0.06
0.06
δ
δ
0.04
0.02
0
0.04
0.02
0
0.1
0.1
µ
µ
0.01
0.01
0.001
Initial
0.001
500 h
F/2.5 V
1000 h
Initial
500 h
1µF/6.3 V
1000 h
2.2
µ
70
Tantalum Capacitors
SVS Series
Impedance – Frequency Characteristics
P Case
1000
100
10
4.7 µF/6.3 V
6.8 µF/6.3 V
10 µF/6.3 V
1
0.1
1 k
10 k
100 k
Frequency (Hz)
1 M
10 M
71
Tantalum Capacitors
Tape and Reel Specifications
• TAPE AND REEL SPECIFICATIONS
Carrier Tape
Sprocket hole
D
Embossment
A
0
t
P
P
2
P
0
D
1
K
Direction of feed
+0.1
Case
Code
EIA
W±0.3 F±0.05
E±0.1
P±0.1
P2±0.05
P0±0.1
D0
0
A0±0.2
B0±0.2
K±0.2
D1 Min.(*)
t
+0.004
Code
(±0.012) (±0.002) (±0.004) (±0.004) (±0.002) (±0.004)
(±0.008) (±0.008) (±0.008)
0
P
A2
A
2012
3216L
3216
3528L
3528
-
1.4
2.2
(0.055) (0.087)
1.4
(0.055)
1.9
3.5
(0.075) (0.138)
8
3.5
φ1.0
0.2
1.9
(0.315) (0.138)
4
(0.039) (0.008)
(0.075)
B3
B2
B
(0.157)
3.2
3.8
1.4
(0.126) (0.150)
(0.055)
1.75
2
4
φ1.5
3.3
3.8
2.1
(0.069)
(0.079)
(0.157) (0.059)
(0.130) (0.150)
(0.083)
3.1
5.1
2.6
0.3
(0.122) (0.201)
(0.102)
C
6032
-
(0.012)
3.7
6.4
3.0
12
5.5
φ1.5
(0.146) (0.252)
(0.118)
(0.472) (0.217)
(0.059)
0.4
D2
D
8
5.1
6.2
3.6
(0.315)
(0.016) (0.201) (0.244)
(0.142)
7343
0.3
4.8
7.7
3.3
(0.012) (0.189) (0.303)
(0.130)
( ): φ 330 only
*
Leader and Trailer
Unit: mm (inch)
Start
End
Leader
(No Component)
Trailer
(No Component)
Components
160 (6.299) min.
400 (15.748) min.
Direction of Feed
102
Tantalum Capacitors
Tape and Reel Specifications
Reel
W
1
B
D
R
W
2
Unit: mm (inch)
A±0.2
C±0.5
D±0.5
B±0.5
R
Tape Width
N Min.
W1
W2 Max.
(±0.079)
(±0.020)
(±0.020)
(±0.020)
8
φ178
φ20
φ13
φ21
2
10±1.0
14.5
1
(0.315)
(7)
(1.969)
(0.512)
(0.827)
(0.079)
(0.394±0.039)
(0.571)
(0.039)
12
14.5±1.0
18.5
(0.472)
(0.571±0.039)
(0.728)
8
φ330
φ80
φ13
φ21
2
9.5±0.5
14.5
1
(0.315)
(13)
(3.150)
(0.512)
(0.827)
(0.079)
(0.374±0.020)
(0.571)
(0.039)
12
13.5±0.50
18.5
(0.472)
(0.531±0.020)
(0.728)
[QUANTITY PER REEL]
Case Size
φ178
3,000
3,000
2,000
3,000
2,000
1,500
500
φ330
-
P
A2
10,000
9,000
10,000
5,000
5,000
2,500
A
B3
B2
B
C, D2, D
103
Tantalum Capacitors
Notes on Correct Use
Notes on Correct Use
1. Circuit Design
(1) Expecting Reliability
The reliability of the solid tantalum capacitor is heavily influenced by environmental conditions such as
temperature, humidity, shock, vibration, mechanical stresses, and electric stresses including applied voltage,
current, ripple current, transient current and voltage, and frequency. When using solid tantalum capacitors,
therefore, provide enough margin to theses conditions, so that the reliability of the capacitors is maintained.
Voltage and temperature are important
parameterswhenestimatingthereliability
1.0
0.9
0.8
100
(field failure rate).
7
The field failure rate of a solid tantalum
capacitorcanbecalculatedbythefollowing
expression if emphasis is placed only on
the voltage and temperature:
4
2
0.7
0.6
0.5
80
70
60
50
40
30
20
The figure indicates an
operation example under
the following conditions:
Ambient temperature: 25 °C
Working voltage ratio: 0.3
Where the multiple of the
failure rate is F = 4 × 10–4
Therefore, estimated failure
rate λ is:
10–1
10–2
10–3
10–4
10–6
7
4
2
0.4
0.3
λ = λ0 (V/V0)3 × 2 (T–T )/10
0
7
4
λ = 2 × 10–5 × 4 × 10–4 = 8 (Fit)
where,
2
Note Where λ = 2%/1000 h
0
λ : estimated failure rate in actual
working condition temperature:
T, voltage: V
7
4
0.2
0.1
2
7
4
λ0 : failurerateunderratedload(See
table below.)
2
temperature: T0, voltage: V0
T
F
V
Failure Rate
This figure graphically indicates (V/V0)3 × 2(T–T )/10 in the expression λ =
0
Series
Failure Rate
1%/1000 h
1%/1000 h
1%/1000 h
0.5%/1000 h
1%/1000 h
1%/1000 h
λ0 (V/V0)3 × 2(T–T )/10. By using this figure, the estemated failure rate can
0
R (standard)
R (extended)
SVS
be easily calculated.
Connect the desired temperature and voltage ratio with a straight line
(form the leftmost vertical axis in the figure to the rightmost axis) in the
figure. The multiple of the failure rate can be obtained at the intersection
of the line drawn and the middle vertical axis in the figure.
Therefore
SVH
SVF
SVZ
λ = λ0 × F.
where,
<Test Conditions>
F: multiple of failure rate at given temperature and ratio of working
voltage to rated voltage.
Temperature: 85˚C
Voltage: Rated Voltage
Rs: 3 Ω
104
Tantalum Capacitors
Notes on Correct Use
2. Ripple Voltage
(1) Keep the sum of the DC voltage and peak value of the ripple voltage to within the rated voltage.
(2) If a ripple voltage is applied to the capacitor, the peak value of the ripple voltage must be kept to within the
values shown in the following figures:
100
100
10
1
Case: P, A2, A, B3, B2, B
Case: C, D2, D
@ 25°C
@ 25°C
50 V
50 V
35 V
35 V
25 V
20 V
16 V
10 V
10 25 V
20 V
16 V
10 V
6.3 V
6.3 V
4 V
2.5 V
4 V
2.5 V
1
0.1
0.1
0.1
1
10
100
0.1
1
10
100
Frequency (kHz)
Frequency (kHz)
Time (sec)
Calculate the permissible ripple voltage at a temperature higher than that specified in these figure by using
the following expression;
Vr.m.s (at 50˚C) = 0.7 × Vr.m.s (at 25˚C)
Vr.m.s (at 85˚C) = 0.5 × Vr.m.s (at 25˚C)
Vr.m.s (at 125˚C) = 0.3 × Vr.m.s (at 25˚C)
(3) Keep the negative peak value of the ripple voltage to within the permissible reverse voltage value specified
in the following paragraph 3.
105
Tantalum Capacitors
Notes on Correct Use
3. Reverse voltage
6.3 V 22µF
1 kΩ
0.020
0.018
0.016
0.014
0.012
0.010
A
µ
+
–
+
–
V
(1) Do not apply a reverse voltage to the solid
tantalum capacitor because the capacitor is of
polartype. Ifreversevoltagecannotbeavoided,
it must be applied for a short time and must not
exceed the following value:
16 V 4.7
µ
F
Reverse
Voltage
0.008
0.006
0.004
35 V 1
µ
F
–8 –6 –4 –20.002
0
25 ˚C ..... 10% max. of rated voltage or 3
Vdc, which is smaller
+10 +20 +30 +40
500
16 V 4.7µF
Forward
µ
85 ˚C ..... 5% max. of rated voltage
Voltage
1 000
1 500
2 000
2 500
1 kΩ
125˚C .... 1% max. of rated voltage
A
+
–
–
+
V
(2) The figure on the right shows the relations
between current and reverse voltage.
6.3 V 22µF
4. Applied Voltage
(1) For general applications, apply 70% or less of the rated voltage to the capacitor.
(2) When the capacitor is used in a power line or a low-impedance circuit, keep the applied voltage to within 30%
(50% max.) of the rated voltage to avoid adverse influence of inrush current.
(3) Derated voltage at 85˚C or more.
When using the capacitor at a temperature of 85˚C or higher, calculate reduced voltage UT from the following
expression. Note, however, that the ambient temperature must not exceed 125˚C.
The rated voltage ratio is as shown in the figure on the right.
UR – UC
100
UT = UR –
(T–85)
40
Approx.
63 %
Where,
UR : rated voltage (V)
50
0
UC : derated volage at 125˚C
T : ambient temperature (˚C)
85
125
5. Current (Series Resistance)
Ambient Temperature (°C)
Note Where series protective
resistance of 3 Ω/V is 1
10
As shown in the figure on the right,
reliability is increased by inserting a series
resistance of at least 3 Ω/V into circuits
where current flow is momentary (switch-
ing circuits, charge/discharge circuits, etc).
If the capacitor is in a low-impedance cir-
cuit, the voltage applied to the capacitor
should be less than 1/2 to 1/3 of the DC
rated volage.
1
0.1
0.1
1
1
10
100
Series Resistance (Ω/V)
10
0.1
0.01
Current value (A)
106
Tantalum Capacitors
Notes on Correct Use
6. Mounting
(1) Direct Soldering
Keep in mind the following points when soldering the capacitor by means of jet soldering or dip soldering:
(a) Temporarily fixing resin
Because the chip tantalum capacitors are larger in size and subject to more force than the chip multilayer
ceramic capacitors or chip resistors, more resin is required to temporarily secure the solid tantalum
capacitors. However, if too much resin is used, the resin adhered to the patterns on a printed circuit board
may adversely affect the solderability.
(b) Pad Pattern DesignPttern design
b
a
c
a
Case Size
a
b
c
P
A2, A
B3, B2
B
2.2
2.9
3.0
3.3
4.1
5.4
5.2
1.4
1.7
2.8
1.9
2.3
2.9
2.9
0.7
1.2
1.6
2.4
2.4
2.4
3.7
C
D2
D
The above dimensions are for reference only. If the capacitor is to be mounted by this method, and if the
pattern is too small, the solderability may be degraded.
(c) Temperature and Time
Keep the peak temperature and time to within the following values:
Solder temperature ..... 260˚C max.
Time ............................. 5 seconds max. (10 seconds max. for SVH)
Whenever possible, perform preheating (at 150˚C max.) for smooth temperature profile. To maintain the
reliability, mount the capacitor at a low temperature and in a short time whenever possible.
(d) Component Layout
If many types of chip components are mounted on a printed circuit board which is to be soldered by means
of jet soldering, solderability may not be uniform over the entire board depending on the layout and density
of the components on the bard (also take into consideration generation of flux gas).
(e) Flux
Use resin-based flux. Do not use flux with strong acidity.
107
Tantalum Capacitors
Notes on Correct Use
(2) Reflow Soldering
Keep in mind the following points when soldering the capacitor in a soldering oven or with a hot plate:
(a) Pad Pattern Design
X
G
Z
Case Size
G max.
0.5
Z min.
2.6
X min.
1.2
P
A2, A
B3, B2
B
1.1
3.8
1.5
1.4
4.1
2.7
2.6
5.9
2.9
C
2.9
6.9
2.7
D2
2.7
6.7
2.9
D
4.1
8.2
2.9
The above dimensions are for reference only. Note that if the pattern is too big, the component may not
be mounted in place.
(b) Temperature and Time
Keep the peak temperature and time to within the following values:
Solder temperature ... 260˚C max.
Time: 10 seconds max.
Whenever possible, perform preheating (at 150˚C max.) for smooth temperatue profile. To maintain the
reliability, mount the capacitor at a low temperature and in a short time whenever possible. The peak
temperature and time shown above are applicable when the capacitor is to be soldered in a soldering oven
or with a hot plate. When the capacitor is soldered by means of infrared reflow soldering, the internal
temperature of the capacitor may rise beyond the surface temperature.
(3) Using Soldering Iron
When soldering the capacitor with a soldering iron, controlling the temperature at the tip of the soldering iron
is very difficult. However, it is recommended that the follwoing temperature and time be observed to maintain
the reliability of the capacitor:
Iron Temperature ..... 300˚C max.
Time.......................... 3 seconds max.
Iron Power ................ 30 W max.
108
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