Glass Dielectric Capacitors

www.avx.com
AVX Glass Dielectric
Capacitors
Version 15.2
Glass Dielectric Caps
Index
Introduction
Capacitor Cross Reference Listing....................................................................................................................2
Glass Selector Guide .........................................................................................................................................3
Glass Capacitor Introduction ............................................................................................................4-5
Performance Curves.......................................................................................................................................6-7
Elevated Temperature (ET Series)
Introduction........................................................................................................................................................8
Performance Curves ..........................................................................................................................................9
Axial Lead ...................................................................................................................................................10-11
Radial Lead.................................................................................................................................................12-13
For the following: •
•
•
•
•
Placement of Orders
Delivery
Specifications of Drawing Reviews
Location of Franchised Distributors
Technical Information
Product Capabilities
Applications Assistance
Contact:
AVX Corporation
A Kyocera Group Company
1 AVX Boulevard
Fountain Inn, SC
Tel: (864)967-2150
FAX: (864)228-3470
AVX/Kyocera: your source for multilayer capacitors, glass capacitors, and tantalum capacitors.
See other MLC parts in AVX’s standard Leaded and Chip catalogs.
1
Glass Dielectric Caps
Cross Reference Listing
OLD MILITARY
PART NUMBER
OLD AVX
PART NUMBER SERIES
MIL-C-11272/1
MIL-PRF-23269/1
MIL-C-11272/2
MIL-PRF-23269/2
MIL-C-11272/3
MIL-PRF-23269/3
MIL-C-11272/4
MIL-PRF-23269/4
MIL-C-11272/13
MIL-C-11272/14
MIL-C-11272/15
MIL-PRF-23269/10
CY10
CYR10
CY15
CYR15
CY20
CYR20
CY30
CYR30
CY06
CY07
CY08
CYR51/52/53
DLA
DRAWING
PRODUCT
CONFIGURATION
13004
Axial
13005
Axial
09019
Axial
09020
Axial
13006
Radial
EXAMPLE OF MARKING
13004
Trademark
13005
Trademark
13006
Trademark
09019
Trademark
09020
Trademark
2
NEW DLA LAND AND
MARITIME DRAWING
NUMBER
13004 –––––– DLA Land and Maritime drawing number
-001 –––––– Non-significant dash number
TM 12A
|
Year
Sequential 4 week lot code
code
13005 –––––– DLA Land and Maritime drawing number
-001 –––––– Non-significant dash number
TM 12A
|
Year
Sequential 4 week lot code
code
13006 –––––– DLA Land and Maritime drawing number
-001 –––––– Non-significant dash number
TM 12A
|
Year
Sequential 4 week lot code
code
09019 –––––– DSCC drawing number
-001 –––––– Non-significant dash number
TM 09A
|
Year
Sequential 4 week lot code
code
09020 –––––– DLA Land and Maritime drawing number
-001 –––––– Non-significant dash number
TM 09A
|
Year
Sequential 4 week lot code
code
Glass Capacitors
Selector Guide
CAPACITOR
CHARACTERISTICS
DIELECTRIC TYPES
ELEVATED
TEMPERATURE GLASS
GLASS
13004
13005
13006
ET10
ET15
ET06
ET07
ET08
Capacitance
Range
.5 - 1200
pF
1 - 2400
pF
0.5 to 1200
pF
1.0 to 2400
pF
Standard
Tolerance
±1 to 20%
±1 to 20%
±.25pF to
±20%
±.25pF to
±20%
Minimum
Tolerance
±1% or
±.25pF
±1% or
±.25pF
±.25%
±.25%
Volts
DC
Operating
Volts
100 VDC
300 VDC
500 VDC
300 VDC
50 VDC
50 VDC
Frequency
Operating
Frequency
DC to
UHF
DC to
UHF
DC to
VHF
DC to
VHF
Dissipation
Factor
% @ 1kHz
>100pF
1MHz
<100pF
.1%
@ 25°C
.1%>100pF
.2%<100pF
@ 25°C
1kHz: .1%
@ 200°C
1kHz: 1%
@ 25°C
1kHz: <.1%
@ 200°C
1kHz: <1%
Insulation
Resistance
Meg ⍀
100,000
@25°C
>100,000
100,000
@25°C
>100,000
@ 25°C
>1 x 108 Ohms
@ 200°C
@ 25°C
>1 x 108 Ohms
@ 200°C
Operating
Range
-55°C
to
+125°C
-55°C
to
+125°C
-75°C
to
+200°C
-75°C
to
+200°C
Temperature
Characteristics
+140 ±25
PPM/°C
+140 ±25
PPM/°C
+140 PPM
±25 PPM/°C
+140 PPM
±25 PPM/°C
Lead
Type
Axial
Radial
Axial
Radial
AVX
TYPES
Capacitance
Temperature
Form
Factor
3
Glass Capacitors
Introduction
INTRODUCTION
For the 1% of designs where you can’t stand failures:
In most types of electronic equipment, the occasional failure
of a capacitor is tolerable – though it is inconvenient and
often costly. For these applications, an acceptable level of
reliability is provided by many of the excellent types of capacitors available today.
But in a few designs you can’t stand failures – satellite
systems, undersea cable repeaters, mountaintop microwave
relay stations, to name just a few. For these designs AVX
glass capacitors may be the optimum choice.
Where reliability is critical and replacement of a failed part is
not possible or practical, consider glass capacitors.
Where stability is essential, even in severe environments,
consider glass capacitors.
Glass capacitors have experienced over four decades of
usage in some of America’s most demanding circuit applications. Among these are:
TDRSS
GOES
Cassini
Mercury
Gemini
Titan II
Saturn IV
Trident
Space Shuttle
Galileo
Matrix
Hubble Space Telescope
Phalnyx
Standard Missile
Minuteman Missile
AWACS
Delta II
MK-46 Torpedo
OVER 5 DECADES OF MAJOR
PROGRAM EXPERIENCE
RELIABILITY
The reasons for the high reliability of glass capacitors are
straightforward.
• Simple construction — few things to go wrong.
• Glass dielectric — one of the most stable, inert materials
available.
• Thorough inspection — every glass capacitor is individually inspected during production. This testing includes visual
inspection, capacitance check, rated voltage check, and
hermetic seal check (for glass case types).
AVX glass capacitors have been used in virtually all critical
military and space programs for the past thirty-five years.
Increasingly, they are also being used in non-military applications where failures can’t be tolerated and circuit performance is critical.
STABILITY
Capacitor stability, or lack of it, is an inherent characteristic
of the dielectric used. Few materials can match glass for stability, and few companies can match AVX Corporation for
glass technology.
Glass doesn’t corrode or degrade in any way. Glass is not
subject to microfractures, delaminations, and other problems associated with certain crystalline materials. In addition,
axial glass capacitors are hermetically encased in glass, with
a true glass-to-metal seal at the leads. This construction is
practically immune to severe environmental effects such as
shock, vibration, radiation resistance, moisture, salt spray,
and solder heat.
4
RADIATION RESISTANCE
The unique materials and construction techniques involved
with glass capacitors make them ideal for use in radiation
environments. After a total dose of nearly 108 rads (H2O)
glass capacitors exhibit only a minor change in capacitance.
(≤.5%) and an 8% change in dissipation factor. Furthermore,
glass capacitors can operate in fast neutron flux environments of 1 x 1015cm-2sec-1 and experience little or no damage in component parameters.
PREDICTABILITY
The dielectric is formed as a continuous ribbon of glass.
Physical and electrical properties and dimensions are precisely controlled.
This results in every AVX glass capacitor being just like every
other, part-to-part, and lot-to-lot. Couple this built-in predictability with complete performance specifications and you
know what performance to expect before the first prototype
is built.
CONSTRUCTION
Simplicity is the key to reliable construction. There are only
three materials in axial glass capacitors: glass dielectric and
case, aluminum foil electrodes, and wire leads. (Radial
capacitors have a molded case.)
The leads are welded to the electrodes so there are no pressure connections to come loose and no solder connections
to melt.
PERFORMANCE
Quality control and simplicity of design mean that AVX glass
capacitors are close to being a “perfect circuit symbol
capacitance.” Here is what you get with AVX glass capacitors:
• Nuclear Radiation Resistance
• Zero Aging Rate
• High Q Factor
• Large RF Current Capability
• No Piezoelectric Noise
• Low Dielectric Absorption
• ±5ppm Temperature Coefficient Retraceability
• High Breakdown Voltage
• Zero Voltage Coefficient
Specific electrical performance details are given in the AVX
“Performance Characteristics of Multilayer Glass Dielectric
Capacitors” technical paper.
Glass Capacitors
Introduction
Although all AVX glass capacitors are of similar construction,
performance characteristics vary slightly between axial and
radial types due to differences in form factor and lead configuration. The performance descriptions and curves that follow are identified as applying to axial or radial types or both.
GLASS CASE, HERMETICALLY SEALED
WELDED
TERMINATION
GLASS DIELECTRIC
ALUMINUM ELECTRODES
Simplicity of construction, combined with the excellent
dielectric characteristics of glass, make AVX Glass
Capacitors outstanding performers.
Temperature Coefficient: The actual temperature coefficient for glass capacitors is shown in Figure 1. It is a slightly
nonlinear curve varying from +115ppm/°C at -55°C to
+165ppm/°C at +125°C. Temperature coefficient can be
accurately represented by the linear approximation
140±25ppm/°C.
Temperature coefficient is not affected by DC bias voltage
nor by measurement frequency over the range of 1kHz to
1MHz. There is no hysteresis in the T.C. curve and part-topart and lot-to-lot variations are no greater than ±5ppm.
Capacitance drift over the temperature range -55°C to
125°C is no greater than 0.1% or 0.1pF, whichever is larger.
Capacitance Change vs. Temperature: Derived from the
T.C. curve, ⌬C vs. temperature is shown in Figure 2 for both
axials and radials.
Losses vs. Temperature: Maximum dissipation factor (DF)
is 0.1% at 0.1kHz and 25°C. The variation of DF vs. temperature is shown in Figure 3 for radials and Figure 4 for axials.
There is no significant variation in DF or Q with different
capacitance values when measured at 1.0kHz. See losses
vs. capacitance, below, for variations with capacitance value
when measured at 1.0MHz.
Insulation Resistance vs.Temperature: Insulation resistance is greater than 100,000 megohms at 25°C. At 125°C,
insulation resistance is greater than 10,000 megohms.
Capacitance Change vs. Frequency: Capacitance
change vs. frequency is typically less than one percent up to
1MHz. See Figure 5.
Losses vs. Frequency: Dissipation factor at 1.0kHz and
25°C is 0.1% maximum for all axials and for radials greater
than 100pF. DF is 0.2% for radials 100pF and below. The
variation of DF and its reciprocal Q vs. frequency is shown in
Figure 6 for radials and Figure 7 for axials. There is no significant variation in DF or Q with capacitance value when measured at 1.0kHz. See below for losses vs. capacitance value
when measured at 1.0MHz.
Losses vs. Capacitance Value: The variation of Q with
capacitance value when measured at 1.0MHz is shown in
Figure 8 for radials and Figure 9 for axials.
Resonant Frequency vs. Capacitance Value: The frequency at which the capacitor becomes self-resonant is a
function of both capacitance value and lead length. Typical
curves are given in Figure 10 and radials and Figure 11 for
axials.
Voltage Coefficient: Voltage coefficient is zero. There is no
measurable change in capacitance from 0 to full working
voltage. Voltage coefficient remains zero over the full temperature range and at all useful frequencies.
Surge Voltage: AVX Glass capacitors can withstand a
surge voltage of 1500±30 VDC.
Temperature Range: The operating temperature range for
all glass capacitors is -55°C to 125°C with no voltage derating required. Elevated Temperature (ET) capacitor operating
temperature range -75°C to +200°C (with overexposure to
+250°C ≤1 hour (axial) with no performance degradation).
Moisture Resistance: Meets or exceeds all requirements
of applicable DLA Land & Maritime drawings..
Life: When tested under accelerated conditions of 125°C
with 150% of rated voltage applied for 2,000 hours, glass
capacitors meet the requirements listed below. Pre- and
post-test measurements are at 25°C.
Capacitance Change — Less than 0.5% or 0.5pF, whichever is greater, for all glass capacitors.
Dissipation Factor —
13004, 13005 — 0.15% maximum
13006 — 0.25% maximum for values above 100pF, 0.45%
for 100pF and below
Noise: Glass dielectric capacitors have zero piezoelectric
noise due to their unique dielectric material construction.
5
Glass Capacitors
Performance Curves
% Capacitance Change
FIGURE 1
PPM/°C
300
200
100
-55
-35
-15
+5
+25
+45
+65
FIGURE 2
+6
+5
+4
+3
+2
+1
0
-1
-2
-3
-4
-5
+85 +105 +125
-55
-35
-15
Temperature — °C
+45
+65
+85 +105 +125
% Capacitance Change vs. Temperature
Radial and Axial
FIGURE 3
FIGURE 4
0.01
0.01
1 kHz Dissipation Factor
1 kHz Dissipation Factor
+25
Temperature — °C
Temperature Coefficient vs. Temperature
Radial and Axial
0.001
0.0001
0.001
0.0001
0
+50
+100
+150
0
Dissipation Factor vs. Temperature
Radial
+100
+150
Dissipation Factor vs. Temperature
Axial
FIGURE 5
% Capacitance Change
+50
Temperature — °C
Temperature — °C
+4
+2
0
-2
-4
1kHz
10kHz
100kHz
1MHz
Frequency
% Capacitance Change vs. Frequency
Radial and Axial
6
+5
Glass Capacitors
Performance Curves
FIGURE 6
FIGURE 7
10 4
10-1
10 4
10-1
10-3
10 2
Dissipation Factor
10-2
10 3
10-3
10 2
Quality Factor
10 3
Dissipation Factor
10-2
Quality Factor
Dissipation Factor
Quality Factor
Quality Factor
Dissipation Factor
10K
100K
1M
10M
10K
100M
Quality Factor and Dissipation Factor
vs. Frequency
Radial
10M
100M
FIGURE 9
10,000
Quality Factor at 1 mHz
10,000
Quality Factor at 1 mHz
1M
Quality Factor and Dissipation Factor
vs. Frequency
Axial
FIGURE 8
1,000
100
10
100
1,000
1,000
100
10
10,000
100
10,000
1,000
Capacitance – pF
Capacitance – pF
Quality Factor vs. Capacitance
Radial
Quality Factor vs. Capacitance
Axial
FIGURE 10
FIGURE 11
1,000
1,000
Se
lf R
eso
na
100
nc
e
0.0
0.5 Total
1.0 lead
1.5 length
2.0 (inches)
10
10
100
1,000
10,000
Capacitance – pF
Resonant Frequency vs. Capacitance
Radial
Frequency – mHz
Frequency – mHz
100K
Frequency in Hz
Frequency in Hz
100
0.5
1.0 Total
1.5 lead
2.0 length
2.5 (inches)
10
10
100
1,000
10,000
Capacitance – pF
Resonant Frequency vs. Capacitance
Axial
7
Glass/ET Series Caps
Elevated Temperature
HEAT
It’s the enemy of reliable, long-term circuit performance. In many applications, very high temperatures are not a
consideration in circuit design. But in a
few specialized areas, elevated temperatures create very real design problems.
That’s why AVX ET-Series capacitors
keep working at temperatures where
more ordinary capacitors usually
fail...up to 200°C.
And, of course, AVX ET-Series capacitors provide all the high performance,
high reliability characteristics you’ve
come to expect from all AVX glass
capacitors...excellent stability, outstanding capacitance retraceability,
rugged, simple construction to eliminate mechanical problems, and electrical performance specifications among
the best available at any price.
So when the heat’s on your next
design and you can’t alter the environment, choose AVX ET-Series glass
capacitors. That’ll be one less problem
you’ll have to solve.
FEATURES
• Available in both axial and radial
leaded configurations
• Values from 0.5 pF to 2400 pF
• Working temperature range -75°C
to 200°C
• “Burned In” versions available – 50
hours @ 1500 VDC, 25°C
• Simple, rugged design and construction
• Short lead times for most values
STANDARD OPERATING CHARACTERISTICS OF AVX ET-SERIES
AXIAL AND RADIAL LEADED GLASS CAPACITORS
Working Temperature
Temperature Range
Working
Range
Voltage Rating
Capacitance Range
Insulation Resistance
Dissipation Factor
Life
Short Time (1 Hour) Exposure to
Overtemperature (250°C)
Voltage Coefficient
-75°C to 200°C
50 VDC
0.5 pF to 2400 pF
@ 25°C > 100,000 Megohms
@ 200°C > 100 Megohms
@ 25°C < .1% at 1kHz
@ 200°C < 1% at 1kHz
(1000 hours at rated voltage at 200°C)
Post Test Delta C @ 25°C < 2%
DF @ 25°C < 2.5%
IR > 100 Megohms (axials)
IR > 10 Megohms (radials)
No degradation
0
TYPICAL APPLICATIONS
In general, AVX ET-Series glass
capacitors are ideally suited for any
environment where high temperature
could alter or destroy circuit performance. And since they are rated down
to -75°C, ET-Series capacitors are
also useful where cycling to colder
temperatures may be a problem.
Some applications where AVX
ET-Series capacitors have already
proven themselves include:
8
• Oil, well logging and downhole
instrumentation, where frictional or
geothermal heat is a problem.
• Geophysical pressure probes.
• Missile or aerospace applications
where engine or environmental heat
needs to be monitored or may
cause circuit failure.
• Radar or other microwave applications.
• RF output circuitry where conduction or fan cooling cannot be entirely relied upon to remove all of the
heat.
• Space and satellite applications
where temperature changes are
extreme and “zero failures” are a
must.
• Industrial chemical process instrumentation where heat is a part of the
process.
• Instrumentation for monitoring atthe-tool performance in metal
cutting machinery.
• Fire-safe alarm or control circuitry.
Glass/ET Series Caps
Performance Curves
10'
+4
+2
0
-2
-4
1kHz
10kHz
100kHz
Quality Factor
10'
10-2
10'
10-3
Dissipation Factor
10K
1MHz
10-3
10'
Dissipation
10K
100K
Frequency – mHz
10'
Se
Quality Factor
Dissipation Factor
10
1,000
10'
-2
Factor
1M
10M
100M
Quality Factor and Dissipation Factor vs. Frequency
Radial
% Capacitance Change vs. Frequency
Radial and Axial
Quality Factor
10M
Frequency in Hz
Frequency
10-1
1M
100K
Quality Factor
Dissipation Factor
% Capacitance Change
10-1
lf R
eso
na
100
nc
e
0.0
0.5 Total
1.0 lead
1.5 length
2.0 (inches)
10
100M
10
100
1,000
10,000
Capacitance – pF
Frequency in Hz
Resonant Frequency vs. Capacitance
Radial
Quality Factor and Dissipation Factor vs. Frequency
Axial
Frequency – mHz
1,000
100
0.5
10
1.0 Total
1.5 lead
2.0 length
2.5 (inches)
10
100
1,000
10,000
Capacitance – pF
Resonant Frequency vs. Capacitance
Axial
9
Glass/ET Series Caps
Axial Lead Elevated Temperature
ET10E
100
AVX ET-Series axial leaded glass capacitors* are available in
two standard case sizes and in a wide range of values and
tolerances. All feature extremely stable glass dielectric, fused
monolithic construction and true glass-to-metal hermetic
seals at the leads for moisture resistance. All case sizes conform to industry dimensional standards.
AVX
INTRODUCTION
ET15E
511J
AVX
ET10
ET15
PERFORMANCE CHARACTERISTICS
Tolerance: Available tolerances for each capacitance value
are shown in the ordering information table on following page.
Part marking codes are also provided.
Temperature Coefficient: Capacitance exhibits retraceability to within 10 ppm/°C over the temperature range -75°C to
+200°C. See graph on following page.
Voltage Coefficient: Zero
Losses: Extremely low over the entire specified operating
temperature range. Dissipation factor is 1% or less at 200°C
at 1kHz.
Life: Delta C is less than 2% after 1000 hours at rated voltage, 200°C.
Insulation Resistance: Greater than 100,000 megohms at
25°C; greater than 100 megohms at 200°C. More than 100
megohms after life-testing.
Voltage/Temperature Rating: All ET-Series capacitors are
rated at 50 VDC over their operating temperature range of
-75°C to 200°C. No derating is required.
High Voltage Stabilization Screening: A special version
of ET-Series axial leaded capacitors – designated ETR – is
available. These capacitors have been “burned in” at room
temperature for 50 hours at 1500 VDC.
Short Time Overtemperature Exposure: After exposure
to 250°C for one hour, ET-Series capacitors have continued
to perform to specification.
Moisture Resistance: Axial glass capacitors are hermetically sealed in glass, with a true metal-to-glass seal at the
leads. This construction provides practical immunity to environmental effects such as shock, moisture, salt spray and
solder heat.
Leads on CL
within 0.79
(0.031)
W
28.58
(1.125)
Min.
L
T
DIMENSIONS:
Case
Size
ET10
ET15
L
millimeters (inches)
W
Lead Dia.
+0.1 (+0.004)
-0.03 (-0.001)
T
8.74 ± 1.19
4.37 ± 0.79
1.98 ± 0.79
(0.344 ± 0.047) (0.172 ± 0.031) (0.078 ± 0.031)
11.91 ± 1.19
6.76 ± 0.79
2.77 ± 1.19
(0.469 ± 0.047) (0.266 ± 0.031) (0.109 ± 0.047)
5.08
(0.200)
5.08
(0.200)
Note: Standard leads are solder-coated Dumet.
Additional performance details are given in the AVX
“Performance Characteristics of Multilayer Glass Dielectric
Capacitors” technical paper.
MARKING
Back
ET 10E
101J
*Radiation Resistance to the same level as the
CY, CYR axial series.
10
ET
ETR
10
E
AVX
Front
= Glass Capacitor
= Glass Capacitor with “burn in”
= Case Size
= Operating Temperature Range
0705
101
J
AVX
0705
= Capacitance, Coded in pF
= Tolerance
= AVX Corporation
= Date Code
Weight
(grams)
.25 - .50
.75 - 1.25
Glass/ET Series Caps
Part Numbers and Ordering Information
HOW TO ORDER
ET
10
E
Style
Glass Capacitor
Case Size
10
15
Operating
Temperature Range
-75°C to +200°C
101
J
Capacitance Code
Capacitance Tolerance
C
D
F
G
J
K
M
Capacitance Code is expressed in
picofarads (pF). The first two digits
represent significant figures and the
third digit specifies the number of
zeros to follow; i.e. 101 indicates 100
pF. For values below 10 pF, R = decimal point; i.e. 1R5 indicates 1.5 pF.
=
=
=
=
=
=
=
±.25 pF
±.50 pF
±1%
±2%
±5%
±10%
±20%
RATINGS & PART NUMBER REFERENCE (Standard Values)
ET
Part No.
ETR
Part No.
Cap
(pF)
Tolerances
Available
Voltage
DC
Working
C
C, D
C, D
C, D
C, D
C, D
C, D
C, D
C, D
C, D
C, K
C, J, K
C, J, K
C, J, K
C, J, K
C, J, K
C, J, K
C, J, K
C, J, K, M
C, J, K, M
C, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
ET
Part No.
ETR
Part No.
ET10, ETR10
ET10E0R5 *
ET10E1R0
ET10E1R5
ET10E2R2
ET10E2R7
ET10E3R0
ET10E3R3
ET10E3R6
ET10E3R9
ET10E4R3
ET10E4R7
ET10E5R1
ET10E5R6
ET10E6R2
ET10E6R8
ET10E7R5
ET10E8R2
ET10E9R1
ET10E100
ET10E110
ET10E120
ET10E130
ET10E150
ET10E160
ET10E180
ET10E200
ET10E220
ET10E240
ET10E270
ET10E300
ET10E330
ET10E360
ET10E390
ET10E430
ET10E470
ET10E510
ET10E560
ET10E620
ET10E680
ET10E750
ETR10E0R5 **
ETR10E1R0
ETR10E1R5
ETR10E2R2
ETR10E2R7
ETR10E3R0
ETR10E3R3
ETR10E3R6
ETR10E3R9
ETR10E4R3
ETR10E4R7
ETR10E5R1
ETR10E5R6
ETR10E6R2
ETR10E6R8
ETR10E7R5
ETR10E8R2
ETR10E9R1
ETR10E100
ETR10E110
ETR10E120
ETR10E130
ETR10E150
ETR10E160
ETR10E180
ETR10E200
ETR10E220
ETR10E240
ETR10E270
ETR10E300
ETR10E330
ETR10E360
ETR10E390
ETR10E430
ETR10E470
ETR10E510
ETR10E560
ETR10E620
ETR10E680
ETR10E750
Add letter for
tolerance code
above lines.
0.5
1.0
1.5
2.2
2.7
3.0
3.3
3.6
3.9
4.3
4.7
5.1
5.6
6.2
6.8
7.5
8.2
9.1
10
11
12
13
15
16
18
20
22
24
27
30
33
36
39
43
47
51
56
62
68
75
Tolerances
Available
Voltage
DC
Working
ET10, ETR10 (cont’d)
ET10E820
ET10E910
ET10E101
ET10E111
ET10E121
ET10E131
ET10E151
ET10E161
ET10E181
ET10E201
ET10E221
ET10E241
ET10E271
ET10E301
ETR10E820
ETR10E910
ETR10E101
ETR10E111
ETR10E121
ETR10E131
ETR10E151
ETR10E161
ETR10E181
ETR10E201
ETR10E221
ETR10E241
ETR10E271
ETR10E301
82
91
100
110
120
130
150
160
180
200
220
240
270
300
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
50
50
50
50
50
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
ET15, ETR15
ET15E221
ET15E241
ET15E271
ET15E301
ET15E331
ET15E361
ET15E391
ET15E431
ET15E471
ET15E511
ET15E561
ET15E621
ET15E681
ET15E751
ET15E821
ET15E911
ET15E102
ET15E112
ET15E122
ETR15E221
ETR15E241
ETR15E271
ETR15E301
ETR15E331
ETR15E361
ETR15E391
ETR15E431
ETR15E471
ETR15E511
ETR15E561
ETR15E621
ETR15E681
ETR15E751
ETR15E821
ETR15E911
ETR15E102
ETR15E112
ETR15E122
220
240
270
300
330
360
390
430
470
510
560
620
680
750
820
910
1000
1100
1200
Add letter for
tolerance code
above lines.
These capacitors include a “burn in”, see page 10
High Voltage Stablization Screening.
These capacitors include a “burn in”, see page 10
High Voltage Stablization Screening.
Dissipation
Factor vs.
Temperature
% Capacitance
+4
Change vs.
Temperature
Axial
Axial
.01
+2
⌬ C in %
1 kHz Dissipation Factor
Cap
(pF)
0
-2
.001
-4
.0001
50
100
150
200
Temperature – ºC
250
0
25
50
75
100
125
Temperature – ºC
150
175
200
11
Glass/ET Series Caps
Radial Lead Elevated Temperature
INTRODUCTION
ET06
AVX ET-Series radial leaded glass capacitors are available in
a broad range of tolerances and values in three case sizes.
The fused monolithic capacitive element is housed in a
miniature rectangular molded case for high packaging efficiency in circuit board applications. The gold-plated Dumet
leads can be soldered or welded.
ET07
ET06E
101J
AVX
ET08
ET07E
621J
ET08E
202J
AVX
AVX
PERFORMANCE CHARACTERISTICS
L
W
31.75
(1.250)
Min.
1.27 ±0.51
(.050 ±.020)
S
Leads on centerline
within ±0.51 (±.020)
DIMENSIONS:
millimeters (inches)
Case
Size
L
±0.13
(±0.005)
W
±0.25
(±0.010)
T
±0.13
(±0.005)
S
+0.51
(±0.020)
Weight
(grams)
ET06
ET07
ET08
7.62 (0.300)
7.62 (0.300)
12.7 (0.500)
5.08 (0.200)
7.62 (0.300)
7.62 (0.300)
2.92 (0.115)
2.92 (0.115)
2.92 (0.115)
5.08 (0.200)
5.08 (0.200)
10.16 (0.400)
.3 - .4
.4 - .5
.7 - .8
Note: All leads are 24 AWG, 0.51± 0.05 (0.020±0.002) diameter.
Leads are solderable and welded gold-plated Dumet.
MARKING
Additional performance details are given in the AVX
“Performance Characteristics of Multilayer Glass Dielectric
Capacitors” technical paper.
ET 06E
561J
0725
AVX
ET
ETR
06
E
561
J
0725
12
T
AVX
Tolerance: The ordering information table on the opposite
page gives the available tolerances and values. An explanation
of the part marking code is also provided.
Temperature Coefficient: Capacitance exhibits retraceability to within 10 ppm/°C over the temperature range -75°C to
200°C. See graph on following page.
Voltage Coefficient: Zero
Losses: Over the specified temperature range, losses are
very low. At 200°C, 1kHz, the dissipation factor is 1% or less.
Life: Delta C is less than 2% after 1000 hours at rated voltage, 200°C.
Insulation Resistance: 100,000 megohms or greater at
25°C; 100 megohms or greater at 200°C. More than 10
megohms after 1000 hour life-test.
Voltage/Temperature Rating: All ET-Series capacitors are
rated at 50 VDC over the operating temperature range of
-75°C to 200°C. Derating is not required.
High Voltage Stabilization Screening: A special version
of ET-Series radial leaded capacitors – designated ETR – is
available. These capacitors have been “burned in” at room
temperature for 50 hours at 1500 VDC.
Short Time Overtemperature Exposure: After exposure
to 250°C for one hour, ET-Series capacitors have continued
to perform to specification.
= AVX Corporation
= Glass Capacitor
= Glass Capacitor with “burn in”
= Case Size
= Operating Temperature Range
= Capacitance, Coded in pF
= Tolerance
= Date Code
Glass/ET Series Caps
HOW TO ORDER
ET
06
E
Style
Glass Capacitor
Case Size
06
07
08
Operating
Temperature Range
-75°C to +200°C
561
J
Capacitance Code
Capacitance Tolerance
Capacitance Code is expressed
in picofarads (pF). The first two
digits represent significant figures
and the third digit specifies the
number of zeros to follow; i.e.
561 indicates 560 pF. For values
below 10 pF, R = decimal point;
i.e. 1R5 indicates 1.5 pF.
C
D
F
G
J
K
M
=
=
=
=
=
=
=
±.25 pF
±.50 pF
±1%
±2%
±5%
±10%
±20%
RATINGS & PART NUMBER REFERENCE (Standard Values*)
ET
Part No.
ETR
Part No.
Cap
(pF)
ET06E8R2
ET06E9R1
ET06E100
ET06E110
ET06E120
ET06E130
ET06E150
ET06E160
ET06E180
ET06E200
ET06E220
ET06E240
ET06E270
ET06E300
ET06E330
ET06E360
ET06E390
ET06E430
ET06E470
ET06E510
ET06E560
ET06E620
ET06E680
ET06E750
ET06E820
ET06E910
ETR06E8R2
ETR06E9R1
ETR06E100
ETR06E110
ETR06E120
ETR06E130
ETR06E150
ETR06E160
ETR06E180
ETR06E200
ETR06E220
ETR06E240
ETR06E270
ETR06E300
ETR06E330
ETR06E360
ETR06E390
ETR06E430
ETR06E470
ETR06E510
ETR06E560
ETR06E620
ETR06E680
ETR06E750
ETR06E820
ETR06E910
Tolerances
Available
Voltage
DC
Working
ET
Part No.
ETR
Part No.
C, J, K
C, J, K
C, J, K, M
C, J, K, M
C, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
C, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
ET08E112 *
ET08E122
ET08E132
ET08E152
ET08E162
ET08E182
ET08E202
ET08E222
ET08E242
Cap
(pF)
ET06, ETR06
Add letter for
tolerance code
above lines.
8.2
9.1
10
11
12
13
15
16
18
20
22
24
27
30
33
36
39
43
47
51
56
62
68
75
82
91
DC
Working
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
F, G, J, K, M
50
50
50
50
50
50
50
50
50
ET08, ETR08
ETR08E112 **
ETR08E122
ETR08E132
ETR08E152
ETR08E162
ETR08E182
ETR08E202
ETR08E222
ETR08E242
Add letter for
tolerance code
above lines.
1100
1200
1300
1500
1600
1800
2000
2200
2400
These capacitors include a “burn in”, see page 12
High Voltage Stablization Screening.
*Other values may be available - contact AVX
These capacitors include a “burn in”, see page 12
High Voltage Stablization Screening.
Dissipation
Factor vs.
Temperature
% Capacitance
+4
Change vs.
Temperature
Radial
Radial
.01
+2
⌬ C in %
1 kHz Dissipation Factor
Tolerances
Available
Voltage
0
-2
.001
-4
.0001
50
100
150
200
Temperature – ºC
250
0
25
50
75
100
125
150
175
200
Temperature – ºC
13
AMERICAS
EUROPE
ASIA-PACIFIC
ASIA-KED
(KYOCERA Electronic Devices)
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