ALS35H104N4N050 [KEMET]
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 50V, 30% +Tol, 10% -Tol, 100000uF, Chassis Mount, RADIAL LEADED;型号: | ALS35H104N4N050 |
厂家: | KEMET CORPORATION |
描述: | Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 50V, 30% +Tol, 10% -Tol, 100000uF, Chassis Mount, RADIAL LEADED |
文件: | 总32页 (文件大小:2588K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
part of the EVOX RIFA GROUP
, now part of the Evox Rifa Group, is
one of Europe’s leading manufacturers of Large CanAluminium
Capacitors. The Evox Rifa Group is a major global capacitor
manufacturer, offering a wide range of technologies and styles
from production facilities in Sweden, UK, Finland, China and
Singapore.
The ISO9001 approved BHC production plant at Weymouth in
the South of England has been successfully manufacturing
Aluminium Electrolytic Capacitors for the most demanding
applications since 1968.
BHC prides itself on its ability to provide a flexible design service
for unique customer requirements. The company has a history
of working alongside design teams, providing the exact solution
to a particular problem, and unrivalled support in the subsequent
application. BHC recognises that its success depends on the
future of its customers and sees itself not only as a supplier of
technologically superior products but as a partner, mutually
striving with our customers for competitive advantage.
The product development and customer service provided by BHC
is backed by a totally integrated, real time information system
that plays an important role in quality, design, and in all phases
of production from planning to control.
The control offered by the use of information systems over the
manufacturing process is only a part of the quality system that
pervades at every level. Quality is the responsibility of every
member of our team with the emphasis placed on “right first
time” and “continuous improvement”. Quality is the link that
bonds us to our customers. We are committed to not only satisfy
customers’ current needs, but to improve and develop products
in anticipation of their future requirements.
In formal recognition of this BHC has achieved approval to BS
EN ISO 9001.
Manufacturing competitively priced products of the highest
quality is the cornerstone of our success. If you wish to share in
that success then contact us and see for yourself how we can
provide a solution to satisfy your needs without having to make
do with the closest standard available.
REFERENCE DATA
Websiteꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ2
TECHNICAL DATA
Optimised Designꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ3
Capacitor Constructionꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ4
Manufacturing Processꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ5
Electrical Characteristicsꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ6-8
Application and Operationꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ8-10
Life Expectancyꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ10/11
Product Safetyꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ12/13
Quality Assurance Systemꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ14
SCREW TERMINAL CAPACITORS
Introductionꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ15-20
ALS34/35ꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ21-24
ACCESSORIES
Mounting Clipsꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ25
Stud Mounting Kitsꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ26
ORDERING INFORMATIONꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ27/28
DESIGN REQUEST FORMꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀꢀ29
2
Web Site
BHC web site http://www!bhc!co!uk
The web site has been designed and hosted to be content
rich, easy to navigate, and fast to accessꢀ The presentation
of the site has been kept simple in order to avoid large page
sizes that take too long to downloadꢀ The design of the site
is aimed at the requirements of system design engineers and
purchasing personnel and attempts to answer most of the
frequently asked questions that we encounterꢀ
The site content includes static pages and dynamically
generated pages linked to a JAVA databaseꢀ The static pages
cover generic information that will not require updating on a
regular basis, whereas, the dynamic pages relate to data
that may change on a more frequent basisꢀ
The site content is subject to continual change as we try to
best serve the needs of our new
and existing customersꢀ We
welcome any feedback or
constructive comments on ways
we can improve the site, or any
new content or functionality that
you feel should be available
onlineꢀ
Some of the main features and
content of the new web site will
include;
● product selector - dynamic
● specification sheet report generator dynamic
● life expectancy calculator dynamic
● capacitor construction theory static
● electrical characteristics static
● application and operation (eꢀgꢀ mounting, protection,
balancing resistors, etcꢀꢀꢀ) static
● cleaning solutions - static
● product safety - static
● component weights - static
● product approvals - static
● company information static
● download area for literature static
● form requests (quotation, product literature)
3
Optimised Design
Optimised Design Service
Approximately 70% of BHC sales comprise application
specific capacitor designs supplied to medium and large OEM
(original equipment manufacturers) customersꢀ These
designs are neither found in the product catalogue, nor on
the website, but have been optimised through close
consultation with system designersꢀ
There are a number of design changes that can be made to a
standard product that can result in one or more of the
following characteristics being achieved;
● lower cost
● increased CV in the same can size, or
reduced can size for the same CV
● lower ESR resulting in higher ripple current
rating
● special print requirements
All standard and custom designs are
typically verified by generic in-house
endurance testing, surge voltage testing
(according to customers requirements),
mechanical testing for shock and
vibrationꢀ
ECAD Design and
Simulation Software
BHC has developed a proprietary CAD
package called ECADꢀ The principle
functions of ECAD include;
● interface to company
AS400 business system (iꢀeꢀ bill of materials
for procurement)
● creation of manufacturing instructions
● issue / revision control
● real time costing
● design creation
● life expectancy simulation (with website
extension)
● product selector (with website extension)
● specification sheet creation
● design archiving
Using this system BHC application and design engineers are
able to offer a rapid response to technical queries relating
to existing designs or proposals for new applicationsꢀ For
further information on how this service can benefit your
application contact the Technical Sales department at BHC
or Email you enquiry to bhcsales@bhcꢀcoꢀuk marked for the
attention of Technical Salesꢀ
4
Capacitor Construction
Basic Construction of a Capacitor
Aluminium Electrolytic Capacitors
The basic principle of the capacitor is to store electrical
charge (Q in coulombs)ꢀ The potential charge it can hold is
determined by the capacitance (C in Farads) and voltage (V
in volts) and is defined as:-
The aluminium electrolytic capacitor consists basically of
two foils interleaved with an absorbent paper wound tightly
into a cylinderꢀ The main advantage of this type of capacitor
is the high capacitance per unit volume due to its internal
construction which consists of a very thin dielectric layer
and large effective surface areaꢀ
Q = C ꢀ V
The unit of capacitance, the Farad, is the capacitance of the
capacitor between the plates across which there appears a
potential difference of 1 volt when it is charged by 1
coulomb of electricityꢀ The value of capacitance in a basic
capacitor is proportional to the area of the plates and
inversely proportional to the distance between themꢀ Not
only does this distance between the plates have an effect on
capacitance but also the material that occupies the space,
known as the dielectricꢀ
The positive plate, or anode, is made from aluminium foil
which is etched to increase the surface areaꢀ The dielectric
is aluminium oxide, which is formed electrolytically onto the
surface of the foilꢀ This formed oxide layer is very thin,
being proportional in thickness to the forming voltage and
possesses a semiconductor characteristicꢀ The oxide
thickness for a 25 volt working capacitor is in the order of
0ꢀ045 microns
If the space were to be occupied by a perfect vacuum then
cathode
dielectric
A = surface area
+ve
dielectric
-ve
aluminium foil
d
aluminium foil
the capacitance can be determined by:
paper soaked in electrolyte
C = 0 ꢀ A
d
anode
electrolyte solution
A = surface area of the plates in m2
d = distance between the plates
(or dielectric thickness) in m
The negative plate, or cathode, is provided by an electrolyte
solution for two reasons:
0 = permittivity of free space - 8ꢀ85 x 10-12 F/m
● allows good contact with the anode by
permeating all the etched structureꢀ
● repairs any flaws in the oxide layer when the
capacitor is polarisedꢀ
In practice this space is occupied by a dielectric which has a
relative permittivity to that of the vacuum as follows:
MATERIAL
Vacuum
Air
Paper (dry)
Polythene
Insulating oil
Bakelite
Glass
RELATIVE PERMITTIVITY
1ꢀ0
The second foil, usually called the cathode foil, contacts
with the electrolyte reducing the series resistanceꢀ This foil
has a thin stabilized oxide film, and therefore will also
possess a very high capacitanceꢀ Like the anode foil the
cathode is also etched to increase the surface areaꢀ This is
necessary in order to eliminate the effect on the overall
capacitance by the presence of the cathode foilꢀ
1ꢀ0006
2 - 2ꢀ5
2 - 2ꢀ5
3 - 4
4ꢀ5 - 5ꢀ5
5 - 10
Therefore capacitance is determined by:
equivalent circuit
C = 0 ꢀ
ꢀ A
d
r
r = relative permittivity of the dielectric
anode
cathode
1
Ctotal
1
1
=
+
Canode
Ccathode
5
Manufacturing Process
The manufacturing process begins with the
anode foil being electrochemically etched
to increase the surface area and then
formed to produce the aluminium oxide
layerꢀ
Extended cathode
Anode foil
Both the anode and cathode foils are then
interleaved with absorbent paper and
wound into a cylinderꢀ During the winding
process aluminium tabs are attached to
each foil to provide the electrical contactꢀ
Foil tabs
The deck, complete with terminals, is
attached to the tabs and then folded down
to rest on top of the windingꢀ
The complete winding is impregnated with
electrolyte before being housed in a
suitable container, usually an aluminium
can, and sealedꢀ Throughout the process all
materials inside the housing must be
maintained at the highest purity and be
compatible with the electrolyteꢀ
Tissues
Cathode foil
Etching
Forming
Winding
Decking
Before being sleeved and packed each capacitor is aged and
testedꢀ The purpose of ageing is to repair any damage in the
oxide layer and thus reduce the leakage current to a very
low levelꢀ Ageing is normally carried out at the rated
temperature of the capacitor and is accomplished by
applying voltage to the device whilst carefully controlling
the supply currentꢀ The process may take several hours to
completeꢀ Damage to the oxide layer can occur due to
variety of reasons:
● slitting of the anode foil after forming
● attaching the tabs to the anode foil
● minor mechanical damage caused during winding
After completion of the production process a sample from
each batch is taken by the quality departmentꢀ This sample
size is controlled by the use of recognised sampling tables
defined in BS 6001ꢀ
Impregnation
Assembly
Ageing
The following tests are applied and may be varied at the
request of the customerꢀ In this case the batch, or special
procedure, will determine the course of action:
Electrical:
● Leakage current
● Capacitance
● ESR
● Impedance
● Tan Delta
Mechanical/Visual:
● Overall dimensions
● Torque test of mounting stud
● Print detail
Testing
Sleeving
Packing
● Box labels
● Packaging, including packed quantity
6
Electrical Characteristics
Rated Capacitance (CR )
Voltage Proof
This is the designed value of capacitance, usually specified
in micro-Farads (µF), when measured with an aꢀcꢀ voltage
<0ꢀ5V at 100Hz and 20°C, with no bias voltage appliedꢀ The
value of capacitance decreases with frequency and increases
with temperature, the magnitude of variation being
dependent on the capacitor typeꢀ
Values are quoted for each range in the data sheetsꢀ These
values are applicable to insulating sleeves and end discs in
good condition with no scuffs or scratchesꢀ Damage caused
by improper handling may reduce these valuesꢀ
The test involves applying a high dꢀcꢀ voltage, eꢀgꢀ 2500V,
across the insulating sleeve of the capacitor for a period of 1
minuteꢀ During this test period there should be no sign of
breakdown or flashoverꢀ
Capacitance Tolerance
Due to material and manufacturing process variability a
tolerance is specified for the rated capacitanceꢀ For a
typical batch of capacitors the distribution of capacitance
values is generally within ±5% of a nominal valueꢀ
Leakage Current
This is the residual current which continues to flow when
the capacitor has been charged up to a set voltageꢀ At this
voltage its magnitude is determined by the thickness
(forming voltage) and degree of perfection of the dielectric
oxide and foil surface areaꢀ The value of leakage current
will continue to fall, whilst voltage is applied, until a very
low steady state value is reachedꢀ Its value will increase
both with voltage and temperatureꢀ The longer capacitors
are stored with no applied voltage, the higher the initial
leakage currentꢀ More details are given under shelf lifeꢀ
Rated Voltage (UR )
The rated voltage is the value of voltage that may be
applied continuously, within the operating temperature
range of the capacitorꢀ Generally the rated voltage and
category voltage have the same valueꢀ
Surge Voltage
Unless otherwise stated in the data sheets capacitors shall
withstand 1000 cycles at upper category temperature as
described below:
Equivalent Series Resistance
The equivalent series resistance (eꢀsꢀrꢀ) is made up of
several resistive components within the capacitor, including
electrolyte, tissue separators, foils etcꢀ The method of
construction also plays an important roleꢀ For example, the
eꢀsꢀrꢀ can be significantly reduced in some cases by making
multiple connections to the anode and cathode foilsꢀ The
eꢀsꢀrꢀ is both temperature and frequency dependent,
increasing either will cause a reduction in eꢀsꢀrꢀ, as
exemplified by the graph below:
Charge to surge voltage and hold for 30 seconds followed by
a no load period of 5ꢀ5 minutes with the capacitor
disconnected and allowed to discharge internallyꢀ The power
supply used shall be capable of delivering >5 A at the test
voltageꢀ
Short duration surge voltage - certain product ranges are
able to withstand a higher surge voltage but for a shorter
period of timeꢀ Where applicable these capacitors shall
withstand 100 surges at 20°C as described below:
Charge capacitor to rated voltage then charge up to short
duration surge voltage for a period of <500 mS then
discharge completely, followed by a no load period of 5
minutesꢀ Figures for this test, where applicable, are shown
under the range data sheetsꢀ
ESR
20°C
Transient Surge Voltage
55°C
85°C
High voltage capacitors (250V 500V) manufactured by BHC
are capable of withstanding very high transient surge
voltages for short durationꢀ For example, the 400V
capacitors from the ALC10 series have been successfully
tested to 600V for 500ms as an isolated condition, iꢀeꢀ once
per dayꢀ Ultimately the performance of the capacitors under
this type of condition is dependent on four criteria:
100
1000
10000
Frequency - Hz
Impedance (Z)
The impedance is governed by the capacitance (C), eꢀsꢀrꢀ and
inductance (L) of the capacitor and is given by the formula:
● value of the voltage;
● duration;
Z = esr2 + (XL - XC)2
● temperature;
● repetition rate
Where XL = 2ꢀπꢀfꢀL and XC =
1
(2ꢀπꢀfꢀCꢀ)
Given this information BHC can advise on the suitability of a
given capacitor for the applicationꢀ
The impedance is dominated by the capacitive reactance
(XC) at low frequencies and by the inductive reactance (XL)
at high frequenciesꢀ Series resonance occurs when XL = XC at
which point Z = eꢀsꢀrꢀ
Dissipation Factor
The dissipation factor or tangent of the loss angle (tan δ) is a
measure of the deviation from that of an ideal capacitor,
and is related to the capacitance and eꢀsꢀrꢀ values as
follows:-
The impedance is clearly frequency dependent and is
temperature dependent due to the capacitance and eꢀsꢀrꢀ
termsꢀ
Tan δ = 2ꢀπꢀfꢀCꢀesr
Where capacitance (C) and eꢀsꢀrꢀ are at frequency fꢀ
7
Electrical Characteristics
Inductance
Climatic Category
The Climatic Category, in accordance with IEC 68-1, is based
upon three groups of digits which decode as follows:
Some inductance is present in all wound aluminium electro-
lytic capacitors as a result of the construction of the winding
and the tabbingꢀ The value is usually not more than a few
tens of nano-henrys and is more or less constant with
changes in temperature and frequencyꢀ
40 / 085 / 56
LCT
UCT
DH
Ripple Current (IR)
Ripple current, caused by the application of an alternating
voltage waveform, will generate heat inside the capacitorꢀ
The power loss is given by:
Where:
LCT = Lower category temperature °C (eꢀgꢀ 40 = -40°C)
UCT = Upper category temperature °C (eꢀgꢀ 85 = +85°C)
DH = Damp heat test days (IEC 68)
P = Ir2ꢀesr (Watts)
Where:
P = Power loss
Shelf Life
The capacitance, ESR and impedance of a capacitor will not
change significantly after extended storage periods, however
the leakage current will very slowly increaseꢀ BHC products
are particularly stable and allow a shelf life in excess of ten
years at room temperatureꢀ
Ir = Ripple Current (Amps)
The maximum power a capacitor can handle is dependent
upon the style and surface area of the can, the thermal
dissipation factor, and the permissible core temperature rise
within the capacitorꢀ Thus for a given capacitor a maximum
continuous ripple current rating can be establishedꢀ
Capacitors have a maximum designed core temperature
which is higher than the specified maximum ambient
operating temperature for the componentꢀ At lower
ambient temperatures higher ripple currents can be applied
provided the maximum core temperature is not exceededꢀ
Factors are given in the data sheetsꢀ Increased ripple
currents are also possible at higher frequencies, since the
eꢀsꢀrꢀ is lowerꢀ Heat-sinking and forced air cooling will both
aid heat transfer and thus allow higher ripple currentsꢀ
The shelf life is shown in the figure belowꢀ Within region 1
the leakage current should remain within its specified limit
when measuredꢀ In region 2 the leakage current may
initially exceed the specified limit and if the measured value
is higher than twice the specified limit then re-ageing is
recommendedꢀ
85
65
45
25
Note, some additional heat is generated by the leakage
current, but this is normally much less than that generated
by the ripple current and so can be ignoredꢀ
Since the ripple current raises the temperature of the
capacitor, it has a significant effect on the operational life
of the componentꢀ Further details are given under life-
expectancyꢀ
5
-15
-35
-55
1
10
100
Temperature Range
The maximum operating temperature or upper category
temperature is the maximum temperature at which the
capacitor is designed to operate continuouslyꢀ Choice of
foils, electrolyte and encapsulation materials ultimately
determine this figureꢀ
The lower category temperature is the lowest temperature
at which the capacitor is designed to operate continuouslyꢀ
The electrolyte resistivity and viscosity both increase at low
temperatures causing loss of capacitance and increased
eꢀsꢀrꢀ
Thousands of hours
Re-age Procedure
Apply the rated voltage to the capacitor at room
temperature for a period of one hour, or until the leakage
current has fallen to a steady value below the specified
limitꢀ During re-ageing a maximum charging current of
twice the specified leakage current or 5mA (whichever is
greater) is suggestedꢀ
8
Electrical Characteristics
Application & Operation
Change in Electrical Characteristics
Various electrical parameters will alter with frequency, temperature and voltage as shown:
Temperature
increase
Frequency
increase
Voltage
increase
Time
under voltage
Capacitance
ESR
Impedance
(below resonance)
Impedance
(above resonance)
DC leakage
APPLICATION AND OPERATION
transient conditions but offer the possibility of exposing one
half of the bank to full voltage should one capacitor short
circuitꢀ
Aluminium electrolytic capacitors are used in a wide variety
of applications including; power supplies, inverters for
variable speed drives and uninterruptible power supplies,
energy discharge (for medical and photoflash applications)
and motor startingꢀ Their advantages over other capacitors
are:
Full details on the selection and use of shunt resistors can
be found in a technical article, TD001, in Aluminium
Electrolytic Capacitors - Application Notes, available
from BHC&
● high capacitance per unit volume
● high ripple current capability
In parallel operation, particularly large, high voltage banks,
the possibility of capacitors discharging into each other may
entail special precautions in certain applicationsꢀ
For optimum performance of this type of capacitor the
following points should be considered:
Series/Parallel Bank Protection
Parallel and Series Operation
There are three major configurations to consider in
protecting a series/parallel bank of capacitorsꢀ The
advantages and disadvantages of each are outlined below
but the final choice must be made by the equipment
designerꢀ
Special considerations arise when electrolytic capacitors are
used in series or parallel banksꢀ
In series operation, matching of capacitance values may be
necessary to avoid imbalance during charging and
discharging modeꢀ Steps must be taken to ensure adequate
dꢀcꢀ voltage distribution while biased, either by providing
shunt resistors to compensate for inequalities in capacitor
dꢀcꢀ leakage currents, or some other meansꢀ
OPTION 1 - Fusing for whole bank
There are two major configurations to consider when
constructing a series/parallel bank of capacitors - individual
balancing resistors and common centre connectionꢀ
Individual balancing resistors afford greater protection for
the capacitors if one becomes short circuit but is more
complex to construct and expensiveꢀ Common centre
connections give improved balancing during steady state and
9
Application & Operation
Advantages
● Simple construction
● Inexpensive
The life expectancy of a capacitor at full rated voltage is
multiplied by the voltage deration factor to obtain the new
life expectancy at the lower operating voltage:
(Vop)
(Vr)
Disadvantages
Le
= Le x Kv
● Only offers basic protection
(Vop)
Le
(Vr)
Le
Kv
● Cannot protect against internal discharges within bank
- Life expectancy at operating voltage
- Life expectancy at rated voltage
- Voltage deration factor
OPTION 2 - Individual capacitor fuses
Polarity and Reversed Voltage
Aluminium Electrolytic capacitors manufactured for use in
dꢀcꢀ applications contain an anode foil and a cathode foilꢀ As
such they are polarised devices and must be connected with
the +ve to the anode foil and the -ve to the cathode foilꢀ If
this were to be reversed then the electrolytic process that
took place in forming the oxide layer on the anode would be
recreated in trying to form an oxide layer on the cathodeꢀ In
forming the cathode foil in this way heat would be
generated and gas given off within the capacitor usually
leading to catastrophic failureꢀ
Advantages
● Removes faulty capacitor from circuit
The cathode foil already possesses a thin stabilised oxide
layer, this thin oxide layer is equivalent to a forming voltage
of approximately 2Vꢀ As a result, the capacitor can withstand
a voltage reversal of up to 2V for short periodsꢀ Above this
voltage the formation process will commenceꢀ
Disadvantages
● Expensive
● Complex assembly (busbars and fuses)
OPTION 3 - Electronic monitoring
Aluminium electrolytic capacitors can also be manufactured
for use in intermittent aꢀcꢀ applications by using two anode
foils in place of one anode and one cathodeꢀ
Advantages
● May prevent serious failure by early shut down of
equipment
● Optional bank discharge mechanism to prevent
capacitors dumping charge into failed capacitor
Case Polarity - due to the presence of electrolyte in the
capacitor the aluminium can, stud mounting and any dummy
pins will essentially be at the same potential as the negative
terminalꢀ BHC therefore recommend that they are either:
Disadvantages
● Must be designed into control circuitry
● Complex and expensive
● left unconnected
● connected to the same potential as the negative
terminal
● insulated
Voltage Deration
If capacitors are operated at a voltage below their rated
value then the reduced stress and lower leakage current will
give an improvement in the life expectancyꢀ
Mounting
All aluminium electrolytic capacitors incorporate a safety
vent, in order to relieve build up of internal pressure due to
over stress or catastrophic failureꢀ For the smaller ranges,
such as snap-in or solder pin types, this takes the form of a
weakened area in the side or base of the canꢀ For the larger,
screw terminal types the vent is incorporated in the deckꢀ
Since leakage current increases with temperature the
benefit of a reduced operating voltage is more pronounced
at higher temperaturesꢀ The graph below shows the voltage
deration factor (Kv) for products with a rated temperature
of 85°C and core temperatures (Tc) of 45°C, 65°C and 85°Cꢀ
In all cases consideration must be given, when mounting the
capacitor, to the operation of the vent under failure
conditionsꢀ It is recommended that capacitors are always
mounted with the safety vent uppermost, or in the upper
part of the deviceꢀ Should the vent operate the least amount
of electrolyte will then be expelledꢀ
1ꢀ5
1ꢀ45
1ꢀ4
1ꢀ35
1ꢀ3
It is worth noting that screw terminal capacitors may be
mounted in any position so long as the vent can operateꢀ
The operational and parametric performance is totally
unaffected by the physical orientation but should the vent
operate with the capacitor mounted upside down then a few
drops of electrolyte may be expelledꢀ
1ꢀ25
1ꢀ2
1ꢀ15
1ꢀ1
1ꢀ05
1
70
75
80
85
90
95
100
Mounting continued overleafꢀꢀꢀꢀ
% of rated voltage
10
Application & Operation
Life Expectancy
Mounting continuedꢀꢀꢀꢀ
Alcohols
Board mounting types are designed to be mounted by their
terminals aloneꢀ Larger types may have dummy pins for
extra rigidityꢀ Screw terminal and tag ended types may be
fixed with a base stud or suitable mounting clampꢀ
Component cleaning using solvents such as isopropanol,
methanol, ethanol, and propanol would not normally have
any detrimental effects and therefore do not require any
special precautionsꢀ
Adequate space should be allowed between components for
cooling air to circulate, particularly when high ripple
currents are being appliedꢀ
Aqueous cleaning methods
Aqueous cleaning methods in conjunction with saponification
may be usedꢀ However, it is recommended that immediate
drying of the component in hot air at approximately 85°C for
at least 5 minutes is carried outꢀ
Altitude and Low Air Pressure
All capacitors manufactured by BHC are hermetically sealed
and should therefore suffer no electrolyte seepage even
under vacuum conditionsꢀ Additionally the electrical
parameters of capacitance, esr, impedance and leakage
current will be unaffectedꢀ
Water can become entrapped beneath the sleeve and unlike
the solvents used above may not be adequately dispelled by
evaporation at room temperatureꢀ Trapped water can cause
the hydration and discolouration of the surface of the
aluminium can, however this is in no way detrimental to the
functioning of the capacitorꢀ
If a capacitor is operated at altitude, however, the life will
be affected slightly for two reasonsꢀ Convected heat loss
will be reduced as the air density falls resulting in the
capacitor running hotter with a consequent reduction in lifeꢀ
Halogenated Hydrocarbons
Halogenated Hydrocarbons contain CFCs and as such are
ozone depleting chemicals (ODCs)ꢀ It is not recommended
that they are used as cleaning solventsꢀ In addition these
solvents can be injurious to electrolytic capacitors by
absorption into the rubber seals followed by subsequent
diffusion into the case, and attack of the winding, leading to
premature failureꢀ
As the air pressure drops the differential between the
internal case pressure and external pressure increasesꢀ A
complete vacuum would cause the internal pressure to rise
by 15 psi (approxꢀ)ꢀ If maintained this would lead to
increased electrolyte vapour loss and give a slight reduction
in life expectancyꢀ
BHC will calculate the life expectancy of a capacitor under
other sets of conditions provided as much as possible of
the following data is supplied:
LIFE EXPECTANCY
The life expectancy represents the typical period of time
until the end of life is reached, which in this case is
characterised as follows:
Operating voltage - this should be taken as the sum of the
nominal dꢀcꢀ voltage and the peak of the aꢀcꢀ ripple voltageꢀ
CATASTROPHIC FAILURE
Ripple current - the rms values should be given at each
frequencyꢀ
-
open or short circuit
MECHANICAL FAILURE
operation of safety vent, split sleeving, etc
PARAMETRIC FAILURE
Air temperature - the temperature of the air surrounding or
flowing over the capacitors
-
Thermal aspects - type of cooling, iꢀeꢀ natural convection or
rate of forced air flow (m/s)ꢀ Thermal resistance of heat sink
or chassisꢀ
-
-
-
-
capacitance change > ± 10%
esr > 2 x initial value
End of life criteria - any special end of life conditions if
different from those stated aboveꢀ
impedance > 3 x initial value
leakage current > specified limit
Some circuits may be able to tolerate larger parametric
variations than shown above, in which case the life of the
component will be extended beyond the figures quotedꢀ
Life Expectancy and Thermal Characteristics
A key aspect of the life expectancy calculation is the core
temperature of the capacitorꢀ It is essential to determine
this operating core temperature either by calculation or by
measurementꢀ
The life expectancy data is statistically derived from
extensive endurance testing of standard production
components and data gathered from components in the
fieldꢀ It does not guarantee the performance and BHC
Components cannot assume responsibility for its useꢀ
Heat is generated inside the capacitor by the effect of ripple
current which raises the core or hot-spot temperature above
that of the ambient airꢀ Heat is also generated by the
leakage current, however this is normally small enough to be
ignoredꢀ
Reducing the stress level on the capacitor (iꢀeꢀ lower
voltage/current/temperature) will increase the life
expectancy, as will improved coolingꢀ
Other circuit components in close proximity will also
contribute to the heating of the capacitorꢀ As will any
mechanical connections to the capacitor, such as the
continued on next pageꢀꢀꢀꢀ
11
Life Expectancy
mounting method, which is at a higher temperature than the
ambient airꢀ Under steady state conditions, when thermal
equilibrium has been reached, the heat generated will be
exactly balanced by the heat lossꢀ
A full technical article, TD003, is included in Aluminium
Electrolytic Capacitors - Application Notes, available
from BHC, which explains life expectancy and thermal
characteristics in more detail& Included in the article is an
explanation of how to calculate life expectancy by the
end user&
If we consider only the loss of heat generated within the
capacitor, and ignore heat absorbed from surrounding
components and through the mounting arrangement, we
arrive at the simplified thermal equivalent circuit shown
belowꢀ
Life Expectancy and Rated Ripple Current
When ripple current is applied to a capacitor the most
important parameter in relation to the life expectancy is the
esrꢀ The value of esr will slowly increase throughout the life
of the capacitor, leading to a gradual increase in power loss
and hence core temperature riseꢀ
Core temp
Long term endurance testing, with voltage and ripple
current applied, has established the characteristic
parameter changes which are displayed by each product
familyꢀ The typical esr characteristic is shown below:
Rhc
Can temp
Rbp
ESR
Increase
Life
Rca
Rpa
Careful study of these curves has enabled the development
of a mathematical model to simulate the changes in esr
which occur under various test conditions and level of stressꢀ
Ambient temp
The results of these mathematical models is included in a
full technical article, TD004, in Aluminium Electrolytic
Capacitors - Application Notes, available from BHC& The
article includes graphs for most products which allow life
expectancy to be extrapolated, based on rated ripple
current and ambient air temperature&
Thermal resistance factors:
Rhc = Hot-spot to can
Rca = Can to ambient air
Rbp = Can base to mounting plate
Rpa = Mounting plate to ambient air
Total thermal resistance from hot-spot to ambient air is
given by:
Rha = Rhc + 1/(1/Rca + 1/(Rbp + Rpa))
measured in °C/W
In each case the thermal resistance factors shown are
effectively a lumped combination of conduction, convection
and radiationꢀ
The method of construction, standard or extended cathode,
will determine the Rhc valueꢀ The values of Rca and Rpa will
vary according to the level of airflow, if anyꢀ The value of
Rbp will depend upon the characteristics of the material
placed between the aluminium base of the can and the
mounting plate (iꢀeꢀ insulating end discs and/or thermal
pads) and also on the pressure holding the capacitor against
the mounting plateꢀ
BHC have carried out extensive testing to establish the
thermal resistance of the hot-spot to ambient, Rha, for each
case size across each rangeꢀ From this data, life expectancy
can be calculated for both standard and special designs
under most operating conditionsꢀ
12
Product Safety
THESE NOTES SHOULD BE READ IN CONJUNCTION WITH THE PRODUCT DATA SHEETꢀ FAILURE TO OBSERVE THE
RATINGS AND THE INFORMATION ON THIS SHEET MAY RESULT IN A SAFETY HAZARDꢀ
WARNING
When potentially lethal voltages e&g& 30V a&c& (r&m&s) or 60V d&c& are applied to the terminals of this product, the use of
a hazard warning label is recommended& In the case of motor start capacitors they meet the requirements of British
Standard Specifications BS&5267:1976 and reference should be made to Appendix C - Guide for installation and
operation&
2! PHYSICAL FORM
1! MATERIAL CONTENT
These capacitors are cylindrical, with axial, radial or screw
terminationsꢀ
Electrolyte
Aluminium electrolytic capacitors contain liquids
(electrolytes) which can be hazardousꢀ The electrolytes are
conducting solutions of organic and/or boric acid,
neutralised with amines or ammonia, in a variety of
solventsꢀ
3! INTRINSIC PROPERTIES
Operating
DꢀCꢀ capacitors are polar devices, and will operate safely
only if correctly connectedꢀ Reversing the connections will
result in high leakage currents which could subsequently
cause short circuit failure, rupture of the safety vent and
possibly explosion and fireꢀ
The major solvents are butyrolactone and ethylene glycolꢀ
Co-solvents eꢀgꢀ N-methyl pyrolidone may be presentꢀ
Inorganic or organo-phosphates are present in low
concentrationꢀ
The physical, chemical and toxicological properties of the
electrolytes are largely determined by the solvents, as
summarised below:
Correctly polarised operation may result in the above failure
modes if:
- the surge voltage is exceededꢀ
- the ambient temperature is too highꢀ
- excessive ripple currents are appliedꢀ
AꢀCꢀ typres are non-polarꢀ Catastrophic failure may be
caused by:
Physical Properties
1ꢀ Low viscosity - typically 5 - 50 cp at 25°C
2ꢀ Combustible - Flash points 95 - 120°C
- Abnormal duty cyclesꢀ
3ꢀ Low vapour pressure - < 20mm Hg at 25°C
- Voltage in excess of rated valueꢀ
- Ambient temperature too highꢀ
Chemical properties
1ꢀ Non-corrosiveꢀ
Non Operating
Aluminium electrolytic capactiors contain liquids which can
leak out (see material content)ꢀ
2ꢀ Can be aggressive to many plastics, lacquers and
resinsꢀ
3ꢀ Totally soluble in hot waterꢀ
Damage to the encapsulation may cause leakage of the
electrolyteꢀ Excessive torque or soldering heat may affect
the performance of the capacitor or damage the sealingꢀ
Toxicology
The electrolytes are moderately toxic, with LD50 values in
the range 1ꢀ5 - 2g/Kgꢀ
Electric shock may result if capacitors are not dischargedꢀ
Skin exposure can cause drying and de-fattingꢀ Severe
irritation may be caused to the mucous membranes,
particularly the eyes, where conjunctivitis may resultꢀ
4! FLAMMABILITY
Most plastics and elastomers are combustible, iꢀeꢀ will ignite
if an ignition source is applied under suitable conditions of
temperature and oxygen levelꢀ For most published data the
UL94 Horizontal or Vertical Burning System has been appliedꢀ
Although useful for comparative values, this test is not
practicable, as the ignition characteristics are strongly
influenced by the material dimensions, and other materials
with which they may be in intimate contactꢀ
Safety Precautions
In the event of electrolyte escape, wash the affected area
with hot waterꢀ Use rubber gloves to avoid skin contactꢀ
Any contact with the eyes should be liberally irrigated with
water, and medical advice soughtꢀ
Note - the electrolyte systems do not contain materials
currently listed as carcinogenic, mutagenic or teratogenic,
eꢀgꢀ polychlorinated biphenyls (PCBs), dimethylformamide
(DMF) or dimethylacetamide (DMA)ꢀ
The capacitor case may be aluminium, polycarbonate or
Norylꢀ Aluminium cans are usually sleeved with PVC or
polyolefinꢀ
BHC has completed a series of flammability tests based on a
Needle Flame Test as specified in IEC 695-2-2ꢀ Full details of
the tests undertaken on both the external components, and
internal wind elements, can be found in a full technical
article, TD005, Flammability Characteristics contained
within BHC Aluminium Electrolytic Capacitors Application
Notesꢀ
Other Materials
The end seal (cover) may be nylon, phenolic or
polybutylteraphthallate (PBT) or an EPR rubber/phenolic
laminateꢀ
Sealing rings and pressure vents are EPR or silicone rubberꢀ
13
Product Safety
5! DISPOSAL
8! DIELECTRIC ABSORPTION
Aluminium Electrolytic Capacitors are consignable waste
under the Special Waste Regulations 1996 (Statutory
Instrument 1996 No 972), which complies with the EC
Hazardous Waste Directive - Directive 91/689/EECꢀ The
electrolyte should therefore be treated as a hazardous waste
and advice should be sought from the local office of the
Environmental Agency regarding its disposalꢀ In the United
Kingdom there are two possible methods of disposal; high
temperature incineration and land fill, from which the user
should seek the best practicable environmental optionꢀ
A phenomenon known as dielectric absorption can cause
aluminium electrolytic capacitors to re-charge themselvesꢀ
The phenomenon is well known but impossible to predict
with any great accuracy and so potentially any electrolytic
product could be affectedꢀ Thus, a capacitor, which has been
charged and then completely discharged, will appear to re-
charge itself, if left open circuit and this will manifest itself
as a small voltage across the terminals of the capacitorꢀ
Generally the voltages seen are less than 20 Vdc, however
higher voltages have on occasion been reportedꢀ
Due to the construction of an aluminium electrolytic
capacitor high temperature incineration may cause the
component to explode due to build-up of internal gas
pressureꢀ In addition, incineration may also cause emission
of noxious fumesꢀ If it is decided that this is the best
practicable option then it must be carried out under
controlled conditions and at a minimum temperature of
1200°Cꢀ It should also be confirmed that the incinerator is
authorised under parts A or B of the Environmental
Protection Actꢀ
In order to avoid any problems caused by this voltage BHC
recommends that capacitors be discharged before
connecting to the terminalsꢀ
The alternative is to dispose of them in an engineered lined
land fill site that is licensed to take the materials identified
on this safety sheetꢀ It should be stressed that these
capacitors are not to be disposed of in a land fill site set
aside for domestic wasteꢀ
BHC strongly recommend that if there are any doubts regarding
the disposal of aluminium capacitors that advice be sought
from the local regulating authorityꢀ
In addition BHC would like to request that users of
aluminium electrolytic capacitors respect the needs of the
environment and wherever possible recover as much of the
materials as possible, iꢀeꢀ aluminiumꢀ
6! UNSAFE USE
Most failures are of a passive nature and do not represent a
safety hazardꢀ A hazard may, however, arise if this failure
causes a dangerous malfunction of the equipment in which the
capacitor is employedꢀ Circuits should be designed to fail safe
under the normal modes of failureꢀ
The usual failure mode is an increase in leakage current or
short circuitꢀ Other possible modes are decrease of
capacitance, increase in dissipation factor (and impedance) or
an open circuitꢀ
Capacitors should be used in a well ventilated enclosure or
cabinetꢀ
7! MOUNTING
Care should be taken when mounting by clamp, that any
safety vent in the can is not coveredꢀ
14
Quality Assurance System
BHC recognises that quality is not just a functional part of
the manufacturing process, necessary to maintain order and
control, it is a philosophy that pervades the whole
organisation at every levelꢀ Quality is the responsibility of
every member of the BHC team where the emphasis is
placed on right first time and continuous improvementꢀ
For BHC total quality forms the bond with its customersꢀ It
no longer serves to solely satisfy their current needs but
creates the environment for development and improvement
in order to anticipate and satisfy future requirementsꢀ
Customer Return Analysis
One feature of the quality system concerns the investigation
of field failuresꢀ Components returned from the field for
technical reasons will be subjected to a rigorous
investigation and, unless otherwise specified, a written
report will be providedꢀ The data collected from this
exercise is collated in a database and reviewed by senior
management resulting in corrective actions where necessaryꢀ
Reliability and Failure Rates
In formal recognition of this BHC has achieved the following
approvals for its quality systems:
The reliability of a component can be defined as the
probability that it will perform satisfactorily under a given
set of conditions for a given length of timeꢀ In order to
calculate the reliability for a component the failure rate will
need to be usedꢀ
The site was originally approved in late 1981 to the CECC
quality system and has held the approval ever sinceꢀ The
approval is based upon the requirements of CECC 00 100 and
CECC 00 114 part 1ꢀ
Failure rates for BHC components have been established as a
result of many years of routine endurance testingꢀ Most of
these tests are carried out at rated temperature with full
rated voltage and ripple current appliedꢀ Extensive analysis
of this data has enabled failure rates to be established for
most product ranges with a 60% confidence levelꢀ
In March 1991 the site was also
approved to BS 5750 part 1 which
has now been harmonised in the
European community as EN 9001ꢀ
This standard is the most
comprehensive of the series and is
the Model for quality assurance
in design,
Full details of the reliability and failure rates is included in
a technical article, TD002, in Aluminium Electrolytic
Capacitors - Application Notes, available from BHC&
development,
M/108/CECC/UK
production,
installation
and servicingꢀ It is also known
as BS EN ISO 9001ꢀ Additionally
certain ranges in the motor
start capacitors are approved to
VDE 560ꢀ
The benefits of the total quality
philosophy and systems that BHC
have adopted are evident in the
service it providesꢀ One of the key
concepts underpinning operations
FM 11885
management is optimum batch
size which strikes the perfect
balance between
manufacturing throughput
efficiency and traceabilityꢀ The
customer benefits from this with
the availability
0019/M/IECQ/UK
of the most
cost competitive order quantities and
price, combined with maximum
flexibility in tailoring the product
to their needs, and enhanced
traceability for individual
capacitorsꢀ
560 PART 8
560 PART 22
15
series
Listed here are only samples of the
range of Screw Terminal Capacitors
we can produce$
Electrical characteristics and case
size are just two parameters that
can be optimised by our design
engineers to achieve the exact
product you require$ Please
contact our sales office for more
details$
ALS34/35 Series
Applications:
The ALS34/35 series of screw terminal capacitors meets the
requirements of the North American marketꢀ This range
offers high CV per unit volume coupled with high ripple
currents and long life performanceꢀ
● Industrial and commercial applicationsꢀ
● Power supplies including switch modeꢀ
● UPS systemsꢀ
● Variable speed drivesꢀ
● Frequency Invertersꢀ
Features:
● Welding equipmentꢀ
● Imperial and metric terminalsꢀ The default range
features 10-32 UNF class 2B terminals (style H)ꢀ
● Imperial and metric case sizesꢀ
● Tolerance 10% +30%ꢀ
● 20000 hours life with UR and IR applied at 85°Cꢀ
● Low EꢀSꢀRꢀ
● Energy storage in pulse discharge applicationsꢀ
Capacitance
150µF to 680,000µF
-10% +30%
Range
Capacitance
Tolerance
● High reliabilityꢀ
Voltage
Range
Temperature
range
16V to 500V dꢀcꢀ
-40°C to +85°C
Case sizes
ø1ꢀ375" x 2ꢀ125" (ø35mm x 54mm) to
ø3" x 8ꢀ625" (ø76mm x 220mm)
Note: ø3ꢀ5" (91mm) size available on requestꢀ
16
case sizes
Terminations
Fig! 1 - Terminal Styles A2, B, C, D, E, F, G, H, J, K, L, M
Aluminium inserts with 10-32 UNF Class2B or M5 threads,
maxꢀ torque 2NMꢀ ¼-28 UNF Class2B or M6 theaded inserts
have a maxꢀ torque 4NMꢀ Max torque for stud mounting
M8:4NM and M12:8NMꢀ
S
Safety Vent
V
DT
Terminal availability mm (inches)
TD
Terminal
Case Diameter ø
“+” SIGN
Style 35 (1ꢀ375)
51 (2)
63ꢀ5 (2ꢀ5)
76 (3)
Fig! 2 - Terminal Style A1, R
A1
S
A2
B
C
D
E
Safety Vent
V
DT
TD
F
“+” SIGN
G
H
J
Z = 13mm (R terminal)
or 10mm (A1 terminal)
S
ALS34
K
L
M
R
T (measured
from deck
surface)
Lt
L
Deck dimensions mm (inches)
Case Diameter
35 (1ꢀ375)
51 (2)
63ꢀ5 (2ꢀ5)
76 (3)
V
S ±0ꢀ5 (0ꢀ019)
12ꢀ8 (0ꢀ5)
22ꢀ2 (0ꢀ875)
28ꢀ5 (1ꢀ125)
31ꢀ8 (1ꢀ25)
8 (0ꢀ315)
ØD
13ꢀ7 (0ꢀ539)
15ꢀ8 (0ꢀ622)
19 (0ꢀ748)
ALS35
H
Terminal options
M
Insulating Disk
(preferred options shown in bold)
Terminal
Thread
Style
Height - T Diameter - DT Height - T Diameter - DT Thread depth - TD Drawing
mm
±0ꢀ8
5.5
mm
±0ꢀ5
13
8
inches
±0ꢀ031
0.217
0.281
0ꢀ281
0ꢀ217
0ꢀ125
0ꢀ250
0ꢀ093
0ꢀ250
0.281
0ꢀ125
0ꢀ281
0ꢀ093
0ꢀ281
0ꢀ217
inches
±0ꢀ019
0.512
0.315
0ꢀ512
0ꢀ512
0ꢀ670
0ꢀ670
0ꢀ315
0ꢀ670
0.315
0ꢀ670
0ꢀ512
0ꢀ315
0ꢀ315
0ꢀ590
mm / (inches)
minimum
A1
A2
B
C
D
E
F
G
H
J
K
L
M
M5
M5
M5
M6
10 / (0ꢀ394")
10 / (0ꢀ394")
10 / (0ꢀ394")
10 / (0ꢀ394")
8ꢀ8 / (0ꢀ346")
11ꢀ8 / (0ꢀ465")
5ꢀ5 / (0ꢀ216")
11ꢀ8 / (0ꢀ465")
10 / (0ꢀ394")
8ꢀ8 / (0ꢀ346")
10 / (0ꢀ394")
5ꢀ5 / (0ꢀ216")
10 / (0ꢀ394")
10 / (0ꢀ394")
Figꢀ2
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ1
Figꢀ 2
7.14
7ꢀ14
5ꢀ5
13
13
17
17
8
17
8
17
13
8
1/4-28 UNF class 2B
1/4-28 UNF class 2B
3ꢀ17
6ꢀ35
2ꢀ36
6ꢀ35
7.14
3ꢀ17
7ꢀ14
2ꢀ36
7ꢀ14
5ꢀ5
M5
M6
10-32 UNF class 2B
M6
10-32 UNF class 2B
10-32 UNF class 2B
M5
M5
8
15
R (note 1)
Case Polarity - due to the presence of electrolyte in the
capacitor the aluminium can and stud mounting will
essentially be at the same potential as the negative
terminalꢀ BHC therefore recommends that the stud and can
are insulated (see accessories for insulating nuts)ꢀ
17
case sizes & technical data
DIMENSIONS mm
CASE
D
D
L
L
LT
S
T
M
H
MOUNTING
CLIP
WEIGHT
grams
CODE unsleeved sleeved unsleeved sleeved sleeved
THREAD
±0ꢀ8
34ꢀ9
34ꢀ9
34ꢀ9
34ꢀ9
34ꢀ9
34ꢀ9
34ꢀ9
34ꢀ9
50ꢀ8
50ꢀ8
50ꢀ8
50ꢀ8
50ꢀ8
50ꢀ8
50ꢀ8
50ꢀ8
63ꢀ5
63ꢀ5
63ꢀ5
63ꢀ5
63ꢀ5
63ꢀ5
76ꢀ2
76ꢀ2
76ꢀ2
76ꢀ2
76ꢀ2
76ꢀ2
76ꢀ2
76ꢀ2
76ꢀ2
±0ꢀ8
35ꢀ3
35ꢀ3
35ꢀ3
35ꢀ3
35ꢀ3
35ꢀ3
35ꢀ3
35ꢀ3
51ꢀ2
51ꢀ2
51ꢀ2
51ꢀ2
51ꢀ2
51ꢀ2
51ꢀ2
51ꢀ2
63ꢀ9
63ꢀ9
63ꢀ9
63ꢀ9
63ꢀ9
63ꢀ9
76ꢀ6
76ꢀ6
76ꢀ6
76ꢀ6
76ꢀ6
76ꢀ6
76ꢀ6
76ꢀ6
76ꢀ6
±1ꢀ6
54ꢀ0
±1ꢀ6
55ꢀ1
±1
±0ꢀ5
12ꢀ8
12ꢀ8
12ꢀ8
12ꢀ8
12ꢀ8
12ꢀ8
12ꢀ8
12ꢀ8
22ꢀ2
22ꢀ2
22ꢀ2
22ꢀ2
22ꢀ2
22ꢀ2
22ꢀ2
22ꢀ2
28ꢀ5
28ꢀ5
28ꢀ5
28ꢀ5
28ꢀ5
28ꢀ5
31ꢀ8
31ꢀ8
31ꢀ8
31ꢀ8
31ꢀ8
31ꢀ8
31ꢀ8
31ꢀ8
31ꢀ8
±0ꢀ8
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
7ꢀ14
±1
12
12
12
12
12
12
12
12
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
16
D2C
D2L
D3C
D3L
D4C
D4L
D5C
D5L
K2C
K2L
K3C
K3L
K4C
K4L
K5C
K5L
L3C
L3L
L4C
L4L
L5C
L5L
N3L
N4C
N4L
N5C
N5L
N5R
N6L
N7L
N8L
61ꢀ5
M8
M8
V3/H2/UTE2736
V3/H2/UTE2736
V3/H2/UTE2736
V3/H2/UTE2736
V3/H2/UTE2736
V3/H2/UTE2736
V3/H2/UTE2736
V3/H2/UTE2736
V4/UTE2737
V4/UTE2737
V4/UTE2737
V4/UTE2737
V4/UTE2737
V4/UTE2737
V4/UTE2737
V4/UTE2737
V8
80
95
66ꢀ7
67ꢀ8
74ꢀ5
79ꢀ4
92ꢀ1
80ꢀ5
93ꢀ2
87ꢀ5
M8
115
130
150
165
185
205
165
200
240
275
315
350
385
425
370
430
485
545
600
660
615
700
780
865
950
990
1115
1280
1450
100ꢀ5
112ꢀ5
125ꢀ5
138ꢀ5
151ꢀ5
61ꢀ5
M8
104ꢀ8
117ꢀ5
130ꢀ2
142ꢀ9
54ꢀ0
105ꢀ9
118ꢀ6
131ꢀ3
144ꢀ0
55ꢀ1
M8
M8
M8
M8
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
66ꢀ7
67ꢀ8
74ꢀ5
87ꢀ5
79ꢀ4
80ꢀ5
92ꢀ1
93ꢀ2
100ꢀ5
112ꢀ5
125ꢀ5
137ꢀ5
151ꢀ5
85ꢀ5
104ꢀ8
117ꢀ5
130ꢀ2
142ꢀ9
79ꢀ4
105ꢀ9
118ꢀ6
131ꢀ3
144ꢀ0
80ꢀ5
92ꢀ1
93ꢀ2
98ꢀ5
V8
104ꢀ8
117ꢀ5
130ꢀ2
142ꢀ9
92ꢀ1
105ꢀ9
118ꢀ6
131ꢀ3
144ꢀ0
93ꢀ2
111ꢀ5
124ꢀ5
136ꢀ5
149ꢀ5
98ꢀ5
V8
V8
V8
V8
V11
104ꢀ8
117ꢀ5
130ꢀ2
142ꢀ9
149ꢀ2
168ꢀ3
193ꢀ7
219ꢀ1
105ꢀ9
118ꢀ6
131ꢀ3
144ꢀ0
150ꢀ4
169ꢀ4
194ꢀ8
220ꢀ2
111ꢀ5
124ꢀ5
136ꢀ5
149ꢀ5
155ꢀ5
174ꢀ5
199ꢀ5
225ꢀ5
V11
V11
V11
V11
V11
V11
V11
V11
DIMENSIONS inches
CASE
D
D
L
L
LT
S
T
M
H
MOUNTING
CLIP
WEIGHT
ounces
CODE unsleeved sleeved unsleeved sleeved sleeved
THREAD
±0ꢀ031
±0ꢀ031
1ꢀ39
±0ꢀ062
2ꢀ125
2ꢀ625
3ꢀ125
3ꢀ625
4ꢀ125
4ꢀ625
5ꢀ125
5ꢀ625
2ꢀ125
2ꢀ625
3ꢀ125
3ꢀ625
4ꢀ125
4ꢀ625
5ꢀ125
5ꢀ625
3ꢀ125
3ꢀ625
4ꢀ125
4ꢀ625
5ꢀ125
5ꢀ625
3ꢀ625
4ꢀ125
4ꢀ625
5ꢀ125
5ꢀ625
5ꢀ875
6ꢀ625
7ꢀ625
8ꢀ625
±0ꢀ062
2ꢀ17
2ꢀ67
3ꢀ17
3ꢀ67
4ꢀ17
4ꢀ67
5ꢀ17
5ꢀ67
2ꢀ17
2ꢀ67
3ꢀ17
3ꢀ67
4ꢀ17
4ꢀ67
5ꢀ17
5ꢀ67
3ꢀ17
3ꢀ67
4ꢀ17
4ꢀ67
5ꢀ17
5ꢀ67
3ꢀ67
4ꢀ17
4ꢀ67
5ꢀ17
5ꢀ67
5ꢀ92
6ꢀ67
7ꢀ67
8ꢀ67
±0ꢀ039 ±0ꢀ019
±0ꢀ031
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
0ꢀ281
±0ꢀ039
D2C
D2L
D3C
D3L
D4C
D4L
D5C
D5L
K2C
K2L
K3C
K3L
K4C
K4L
K5C
K5L
L3C
L3L
L4C
L4L
L5C
L5L
N3L
N4C
N4L
N5C
N5L
N5R
N6L
N7L
N8L
1ꢀ375
2ꢀ42
2ꢀ93
3ꢀ44
3ꢀ96
4ꢀ43
4ꢀ94
5ꢀ45
5ꢀ96
2ꢀ42
2ꢀ93
3ꢀ44
3ꢀ96
4ꢀ43
4ꢀ94
5ꢀ41
5ꢀ96
3ꢀ37
3ꢀ88
4ꢀ39
4ꢀ90
5ꢀ37
5ꢀ89
3ꢀ88
4ꢀ39
4ꢀ90
5ꢀ37
5ꢀ89
6ꢀ12
6ꢀ87
7ꢀ85
8ꢀ88
0ꢀ5
0ꢀ5
M8
M8
0ꢀ472 V3/H2/UTE2736
0ꢀ472 V3/H2/UTE2736
0ꢀ472 V3/H2/UTE2736
0ꢀ472 V3/H2/UTE2736
0ꢀ472 V3/H2/UTE2736
0ꢀ472 V3/H2/UTE2736
0ꢀ472 V3/H2/UTE2736
0ꢀ472 V3/H2/UTE2736
2ꢀ8
3ꢀ3
1ꢀ375
1ꢀ39
1ꢀ375
1ꢀ39
0ꢀ5
M8
4ꢀ0
1ꢀ375
1ꢀ39
0ꢀ5
M8
4ꢀ6
1ꢀ375
1ꢀ39
0ꢀ5
M8
5ꢀ3
1ꢀ375
1ꢀ39
0ꢀ5
M8
5ꢀ8
1ꢀ375
1ꢀ39
0ꢀ5
M8
6ꢀ5
1ꢀ375
2
1ꢀ39
0ꢀ5
M8
7ꢀ2
2ꢀ015
2ꢀ015
2ꢀ015
2ꢀ015
2ꢀ015
2ꢀ015
2ꢀ015
2ꢀ015
2ꢀ515
2ꢀ515
2ꢀ515
2ꢀ515
2ꢀ515
2ꢀ515
3ꢀ015
3ꢀ015
3ꢀ015
3ꢀ015
3ꢀ015
3ꢀ015
3ꢀ015
3ꢀ015
3ꢀ015
0ꢀ875
0ꢀ875
0ꢀ875
0ꢀ875
0ꢀ875
0ꢀ875
0ꢀ875
0ꢀ875
1ꢀ125
1ꢀ125
1ꢀ125
1ꢀ125
1ꢀ125
1ꢀ125
1ꢀ25
1ꢀ25
1ꢀ25
1ꢀ25
1ꢀ25
1ꢀ25
1ꢀ25
1ꢀ25
1ꢀ25
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
M12
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
0ꢀ63
V4/UTE2737
5ꢀ8
2
V4/UTE2737
7ꢀ1
2
V4/UTE2737
8ꢀ5
2
V4/UTE2737
9ꢀ7
2
V4/UTE2737
11ꢀ1
12ꢀ3
13ꢀ6
15ꢀ0
13ꢀ1
15ꢀ2
17ꢀ1
19ꢀ2
21ꢀ2
23ꢀ3
21ꢀ7
24ꢀ7
27ꢀ5
30ꢀ5
33ꢀ5
34ꢀ9
39ꢀ3
45ꢀ2
51ꢀ1
2
V4/UTE2737
2
V4/UTE2737
2
V4/UTE2737
V8
2ꢀ5
2ꢀ5
2ꢀ5
2ꢀ5
2ꢀ5
2ꢀ5
3
V8
V8
V8
V8
V8
V11
V11
V11
V11
V11
V11
V11
V11
V11
3
3
3
3
3
3
3
3
18
technical data
TECHNICAL DATA
Related documents
IEC 384-4
Vibration
10Hz to 55Hz at 0ꢀ75mm (0ꢀ0295") or 10g for 3 x 2hrs
durationꢀ Except 220mm (8ꢀ625") long cans 10 - 55Hz
at 0ꢀ35mm (0ꢀ0138") or 5g for 3 x 0ꢀ5hrs durationꢀ
Temperature range
Storage 55°C to +85°C
Operating 40°C to +85°C
Environmental classification 40/085/56
Insulation resistance
100MΩ at 100V dꢀcꢀ, across the insulating sleeveꢀ
Surge voltage
Voltage proof
2500V dꢀcꢀ, across the insulating sleeveꢀ
(1) According to IEC 384-4 at 85°C
Ur < 315Vdc Surge voltage = 1ꢀ15 x UR
Ur 315Vdc Surge voltage = 1ꢀ1 x UR
Ripple current
The following values are approximate only, to give an
indication of the effects of frequency and temperature
on ripple currentꢀ More accurate data can be obtained by
referring to the Application Notes available from
BHC Componentsꢀ
Duty cycle:
1000 cycles at 85°C
Charge to surge voltage and hold for 30s followed by a no
load period of 5ꢀ5minutes with the capacitor
disconnected and allowed to discharge internallyꢀ
(2) At room temperature: 25°C
FREQUENCY CORRECTION
Capacitors shall withstand the rated rꢀmꢀsꢀ ripple current as
given in the table at upper category temperature
in circulating airꢀ For frequencies other than those shown
the following formula should be used:
Rated voltage UR
Surge voltage US
16 25 40 50 63 75 100 160
20 30 50 65 75 95 125 200
Rated voltage UR
Surge voltage US
200 250 300 350 400 450 500
250 300 350 400 450 500 550
F x A2 x B2
Ripple current =
Duty cycle:
1440 cycles at 25°Cꢀ
120 x (B2 - A2) + (F x A2)
Connect the capacitor in series with a current limiting
resistor and apply rated surge voltage at room
temperature for a period of 30 seconds on followed by 4ꢀ5
minutes off during which time the capacitor
A = 120Hz ripple current
B = 20kHz ripple current
F = Required frequency (Hz)
discharges through the current limiting resistorꢀ
Ripple current
TEMPERATURE CORRECTION
For ambient temperature other than 85°C the following
multipliers should be applied to the 85°C ripple currentꢀ
aꢀ For capacitors up to 2500µF the current limiting resistor
is 1000ohms
bꢀ For capacitors greater than 2500µF the current limiting
resistor value is determined by the following equation:
R = (2ꢀ5 x 106) / C Where:
C is in microfarads
R is in ohms
AMBIENT TEMPERATURE
FACTOR
2ꢀ1
1ꢀ9
1ꢀ7
1ꢀ0
50°C
60°C
70°C
85°C
(3) Short duration surge voltage (500 ms)
NꢀBꢀThe sum of the dꢀcꢀ and aꢀcꢀ voltage components
should not exceed the dꢀcꢀ voltage ratingꢀ
RATED VOLTAGE
SURGE VOLTAGE
200
250
350
400
415
450
500
350
400
500
520
530
550
600
Life expectancy
At rated temperature with rated voltage and ripple current
appliedꢀ
Can Diameter (mm)
Life Expectancy (hours)
36
51
63ꢀ5
77
11000
18000
19000
20000
Charge/discharge
106 cycles at 25°C and rated voltageꢀ One cycle per second
with a time constant of 0ꢀ1ꢀ
DC leakage current
After application of rated dꢀcꢀ voltage for 5 minutes at
20°C, the dꢀcꢀ leakage current shall not exceed
(0ꢀ006 x CR x UR) µA or 6mA whichever is the smallerꢀ Where
CR is the rated capacitance in µF and UR
is the rated dꢀcꢀ voltageꢀ
19
imperial capacitor selection
Imperial capacitor selection according to CR, UR, and case size
Listed here are only samples of the range of screw terminal capacitors we can produceꢀ Electrical characteristics and case
size are just two parameters that can be optimised by our design engineers to achieve the exact product you requireꢀ
Please contact our sales office for more detailsꢀ
CR
UR (Volts)
(µF)
16
-
25
-
40
-
50
63
-
75
100
2200
-
-
1ꢀ375 x 2ꢀ125
-
-
-
-
-
1ꢀ375 x 2ꢀ125 1ꢀ375 x 2ꢀ625
3300
4700
-
-
-
-
-
-
2 x 2ꢀ125
-
-
-
-
1ꢀ375 x 2ꢀ125 1ꢀ375 x 2ꢀ625 1ꢀ375 x 3ꢀ125
-
-
-
-
-
2 x 2ꢀ125
-
-
-
-
1ꢀ375 x 2ꢀ125 1ꢀ375 x 2ꢀ625 1ꢀ375 x 3ꢀ125 1ꢀ375 x 4ꢀ125
6800
-
-
-
-
-
2 x 2ꢀ625
2 x 2ꢀ625
-
-
1ꢀ375 x 2ꢀ125 1ꢀ375 x 3ꢀ125 1ꢀ375 x 3ꢀ625 1ꢀ375 x 4ꢀ625 1ꢀ375 x 5ꢀ625
10000
15000
22000
33000
-
-
-
-
2 x 2ꢀ125
2 x 3ꢀ125
2 x 3ꢀ125
-
1ꢀ375 x 2ꢀ125 1ꢀ375 x 3ꢀ125 1ꢀ375 x 4ꢀ125 1ꢀ375 x 5ꢀ125
2 x 3ꢀ625
2 x 4ꢀ125
-
-
-
2 x 2ꢀ125
2 x 2ꢀ625
-
2ꢀ5 x 3ꢀ125
-
1ꢀ375 x 2ꢀ625 1ꢀ375 x 4ꢀ125 1ꢀ375 x 5ꢀ625
2 x 3ꢀ125
2 x 4ꢀ625
2ꢀ5 x 4ꢀ125
-
-
2 x 2ꢀ125
2 x 2ꢀ625
2ꢀ5 x 3ꢀ125
2ꢀ5 x 3ꢀ125
3 x 3ꢀ625
1ꢀ375 x 2ꢀ125 1ꢀ375 x 3ꢀ125 1ꢀ375 x 5ꢀ625
2 x 3ꢀ125
2 x 4ꢀ125
2ꢀ5 x 4ꢀ125
3 x 4ꢀ125
-
2 x 2ꢀ125
2 x 2ꢀ625
2 x 3ꢀ125
2ꢀ5 x 3ꢀ125
2ꢀ5 x 3ꢀ625
3 x 3ꢀ625
-
1ꢀ375 x 3ꢀ125 1ꢀ375 x 4ꢀ125
2 x 4ꢀ125
2 x 5ꢀ125
3 x 4ꢀ125
3 x 6ꢀ625
47000
68000
2 x 2ꢀ125
-
2 x 2ꢀ625
-
-
-
2ꢀ5 x 3ꢀ625
2ꢀ5 x 4ꢀ125
-
-
-
-
-
3 x 3ꢀ625
1ꢀ375 x 4ꢀ125 1ꢀ375 x 5ꢀ625
2 x 2ꢀ625
-
2 x 4ꢀ125
2 x 5ꢀ125
3 x 4ꢀ125
3 x 6ꢀ625
3 x 8ꢀ625
2 x 3ꢀ125
-
2ꢀ5 x 3ꢀ125
2ꢀ5 x 4ꢀ125
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
3 x 3ꢀ625
1ꢀ375 x 5ꢀ625
2 x 3ꢀ125
2 x 4ꢀ125
2ꢀ5 x 3ꢀ125
2 x 5ꢀ125
2ꢀ5 x 3ꢀ625
2ꢀ5 x 5ꢀ625
3 x 3ꢀ625
3 x 5ꢀ625
3 x 8ꢀ625
2 x 4ꢀ125
2ꢀ5 x 3ꢀ125
2 x 5ꢀ625
2ꢀ5 x 3ꢀ625
2ꢀ5 x 5ꢀ625
3 x 3ꢀ625
3 x 5ꢀ625
-
2 x 5ꢀ625
3 x 4ꢀ625
3 x 6ꢀ625
3 x 8ꢀ625
100000
150000
220000
330000
2ꢀ5 x 4ꢀ125
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
3 x 3ꢀ625
3 x 6ꢀ625
-
-
-
-
-
-
-
-
3 x 5ꢀ625
-
3 x 8ꢀ625
-
-
-
470000
680000
3 x 8ꢀ625
-
CR
UR (Volts)
(µF)
150
220
160
200
250
350
-
-
400
-
-
450
500
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
1ꢀ375 x 2ꢀ125
1ꢀ375 x 2ꢀ125 1ꢀ375 x 2ꢀ625
1ꢀ375 x 2ꢀ125 1ꢀ375 x 2ꢀ125 1ꢀ375 x 3ꢀ125 1ꢀ375 x 3ꢀ625
2 x 2ꢀ125 2 x 2ꢀ125
330
-
-
1ꢀ375 x 2ꢀ625 1ꢀ375 x 3ꢀ125 1ꢀ375 x 3ꢀ625 1ꢀ375 x 4ꢀ625
470
2 x 2ꢀ125
2 x 2ꢀ125
2 x 2ꢀ625
2 x 2ꢀ625
1ꢀ375 x 2ꢀ125 1ꢀ375 x 2ꢀ125 1ꢀ375 x 3ꢀ125 1ꢀ375 x 4ꢀ125 1ꢀ375 x 5ꢀ125
2 x 4ꢀ125
680
-
-
2 x 2ꢀ625
2 x 2ꢀ625
2 x 3ꢀ125
2ꢀ5 x 3ꢀ125
1ꢀ375 x 2ꢀ125 1ꢀ375 x 2ꢀ625 1ꢀ375 x 3ꢀ125 1ꢀ375 x 4ꢀ125 1ꢀ375 x 5ꢀ125
2 x 4ꢀ125
2 x 5ꢀ125
1000
1500
2200
3300
4700
6800
10000
-
2 x 2ꢀ125
2 x 2ꢀ125
2 x 3ꢀ125
2 x 3ꢀ125
2ꢀ5 x 3ꢀ125
2ꢀ5 x 3ꢀ625
1ꢀ375 x 2ꢀ625 1ꢀ375 x 3ꢀ125 1ꢀ375 x 4ꢀ125 1ꢀ375 x 5ꢀ625
2 x 4ꢀ125
2 x 5ꢀ125
2ꢀ5 x 4ꢀ125
2 x 2ꢀ125
2 x 2ꢀ625
2 x 2ꢀ625
2 x 3ꢀ625
2ꢀ5 x 3ꢀ125
2ꢀ5 x 3ꢀ625
3 x 3ꢀ625
1ꢀ375 x 3ꢀ625 1ꢀ375 x 4ꢀ625 1ꢀ375 x 5ꢀ625
2 x 4ꢀ625
2 x 5ꢀ125
3 x 3ꢀ625
3 x 4ꢀ625
2 x 2ꢀ625
1ꢀ375 x 4ꢀ625
2 x 3ꢀ125
2 x 3ꢀ625
-
2 x 4ꢀ625
2ꢀ5 x 3ꢀ125
2ꢀ5 x 4ꢀ125
3 x 3ꢀ625
3 x 4ꢀ125
3 x 5ꢀ625
2 x 3ꢀ125
2 x 4ꢀ125
-
2 x 4ꢀ625
2ꢀ5 x 3ꢀ125
2ꢀ5 x 4ꢀ125
3 x 3ꢀ625
3 x 4ꢀ125
-
2 x 3ꢀ125
2ꢀ5 x 3ꢀ125
-
2 x 5ꢀ625
2ꢀ5 x 3ꢀ625
2ꢀ5 x 5ꢀ625
3 x 3ꢀ625
3 x 5ꢀ625
-
2ꢀ5 x 3ꢀ125
2ꢀ5 x 3ꢀ625
-
-
2ꢀ5 x 4ꢀ125
2ꢀ5 x 4ꢀ625
3 x 4ꢀ125
3 x 6ꢀ625
-
3 x 3ꢀ625
-
-
3 x 3ꢀ625
3 x 5ꢀ125
3 x 5ꢀ625
3 x 8ꢀ625
-
-
-
-
-
-
-
-
-
-
3 x 5ꢀ625
3 x 5ꢀ625
3 x 6ꢀ625
-
-
-
-
-
-
-
-
-
-
-
3 x 6ꢀ625
-
-
-
15000
22000
3 x 5ꢀ625
3 x 6ꢀ625
3 x 6ꢀ625
-
20
metric capacitor selection
Metric capacitor selection according to CR, UR, and case size
Listed here are only samples of the range of screw terminal capacitors we can produceꢀ Electrical characteristics and case
size are just two parameters that can be optimised by our design engineers to achieve the exact product you requireꢀ
Please contact our sales office for more detailsꢀ
CR
UR (Volts)
(µF)
16
25
40
50
63
75
100
35 x 54
35 x 67
51 x 54
35 x 79
-
35 x 105
51 x 67
35 x 143
51 x 79
51 x 105
64 x 79
64 x 105
76 x 92
76 x 105
-
2200
-
-
-
-
-
-
-
-
-
-
-
-
35 x 54
3300
4700
-
-
-
-
-
-
-
-
-
35 x 54
35 x 67
-
-
-
-
-
51 x 54
-
-
-
35 x 54
35 x 67
35 x 79
6800
-
-
-
-
-
51 x 67
-
-
35 x 54
35 x 79
35 x 92
35 x 118
10000
15000
22000
33000
47000
-
-
-
-
51 x 54
51 x 79
-
35 x 54
-
35 x 79
35 x 105
35 x 130
51 x 92
-
-
51 x 54
51 x 67
-
-
35 x 67
-
35 x 79
51 x 54
35 x 105
51 x 67
-
35 x 143
51 x 79
-
51 x 105
64 x 79
51 x 143
64 x 92
64 x 143
76 x 92
76 x 143
-
35 x 105
35 x 143
51 x 79
51 x 118
-
51 x 54
51 x 67
64 x 79
64 x 79
35 x 54
-
35 x 143
51 x 79
51 x 105
64 x 105
51 x 67
64 x 79
64 x 92
76 x 92
35 x 79
51 x 54
-
35 x105
51 x67
-
35 x 143
51 x 79
51 x 105
64 x 79
51 x 130
64 x 92
64 x 143
76 x 92
76 x 143
76 x 219
51 x 79
51 x 105
51 x 130
76 x 105
76 x 168
-
-
-
64 x 92
64 x105
-
-
-
76 x 92
-
51 x 105
51 x 130
76 x 105
76 x 168
76 x 219
-
68000
64 x 79
64 x 105
-
-
-
-
-
76 x 92
-
-
51 x 143
76 x 118
76 x 168
76 x 219
100000
150000
220000
330000
64 x 105
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
76 x 92
76 x 168
-
-
-
-
-
-
-
-
-
-
-
76 x 143
-
76 x 219
-
-
-
-
-
-
-
470000
680000
76 x 219
-
CR
UR (Volts)
(µF)
150
220
160
200
-
250
350
400
450
500
-
-
-
-
-
35 x 54
35 x 79
51 x 54
35 x 92
51 x 67
35 x 130
51 x 79
51 x 105
64 x 79
51 x 130
64 x 92
-
35 x 54
-
-
-
-
-
35 x 67
-
-
-
35 x 54
-
34 x 54
-
35 x 92
330
-
-
-
51 x 54
-
-
-
35 x 67
51 x 54
35 x 79
51 x 67
35 x 105
51 x 79
35 x 143
51 x 92
-
51 x 118
64 x 79
64 x 105
-
76 x 92
-
76 x 143
-
76 x 168
-
35 x 79
51 x 54
35 x 105
51 x 67
35 x 130
51 x 79
51 x 105
64 x 79
-
51 x 130
64 x 92
64 x 118
76 x 92
76 x 130
-
35 x 118
470
-
-
-
51 x 67
-
35 x 54
-
35 x 54
-
51 x 105
680
-
64 x 79
35 x 54
-
35 x 67
51 x 54
35 x 79
35 x 105
51 x 67
35 x 118
51 x 79
51 x 105
-
51 x 118
64 x 79
64 x 105
76 x 92
76 x 105
-
35 x 79
51 x 54
35 x 105
51 x 67
-
35 x 143
51 x 79
64 x 79
-
51 x 143
64 x 92
64 x 143
76 x 92
76 x 143
-
51 x 130
1000
64 x 92
35 x 67
51 x 54
-
35 x 92
51 x 67
35 x 118
51 x 79
51 x 92
-
51 x 118
64 x 79
64 x 105
76 x 92
76 x 105
76 x 143
64 x 105
1500
76 x 92
-
76 x 92
-
76 x 105
-
76 x 143
-
76 x 118
2200
3300
4700
6800
10000
-
76 x 168
-
76 x 219
-
-
-
-
-
-
-
76 x 143
-
76 x 168
-
-
-
-
-
15000
22000
76 x 143
76 x 168
76 x 168
-
-
-
-
-
-
-
21
Cap
(µF)
Nominal Case Size
Maxꢀ ESR (mΩ)
Ripple current
(A) at 85°C
Part number
Rated voltage
dꢀcꢀ
mm (inches)
at 25°C
Dia
Len
120Hz
20kHz
120Hz
20kHz
33000
47000
47000
68000
68000
100000
100000
150000
150000
220000
220000
330000
330000
470000
680000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
54ꢀ0 (2ꢀ125)
104ꢀ8 (4ꢀ125)
66ꢀ7 (2ꢀ625)
142ꢀ9 (5ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
130ꢀ2 (5ꢀ125)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
219ꢀ1 (8ꢀ625)
29
20
27
16
19
12
14
10
10
9
26
19
25
14
17
12
13
10
9
8
7
6
8
10ꢀ4
13ꢀ9
11ꢀ1
16ꢀ1
13ꢀ8
17ꢀ1
16ꢀ9
20ꢀ2
23ꢀ2
22ꢀ5
26ꢀ2
32ꢀ2
26ꢀ3
34ꢀ4
46ꢀ5
11ꢀ7
15ꢀ6
11ꢀ8
17ꢀ7
14ꢀ7
18ꢀ3
17ꢀ9
21ꢀ1
24ꢀ5
23ꢀ3
27ꢀ3
33ꢀ2
26ꢀ9
35ꢀ0
47ꢀ1
ALS34H333D2C016
ALS34H473D3C016
ALS34H473K2C016
ALS34H683D4C016
ALS34H683K2L016
ALS34H104D5L016
ALS34H104K3C016
ALS34H154K4C016
ALS34H154L3C016
ALS34H224K5C016
ALS34H224L3L016
ALS34H334L5L016
ALS34H334N3L016
ALS34H474N5L016
ALS34H684N8L016
16V dꢀcꢀ
(20V surge)
8
6
8
6
76ꢀ2 (3)
76ꢀ2 (3)
6
5
5
25V dꢀcꢀ
(30V surge)
15000
22000
33000
33000
47000
47000
68000
68000
100000
100000
150000
150000
220000
220000
330000
470000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
79ꢀ4 (3ꢀ125)
54ꢀ0 (2ꢀ125)
104ꢀ8 (4ꢀ125)
66ꢀ7 (2ꢀ625)
142ꢀ9 (5ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
142ꢀ9 (5ꢀ625)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
219ꢀ1 (8ꢀ625)
38
27
20
27
15
19
12
14
11
10
9
32
23
17
24
13
17
11
12
10
9
8
7
6
8
6
5
9ꢀ2
11ꢀ4
13ꢀ7
15ꢀ8
11ꢀ5
17ꢀ7
14ꢀ4
18ꢀ3
17ꢀ6
20ꢀ9
24ꢀ1
23ꢀ4
26ꢀ7
32ꢀ8
26ꢀ3
34ꢀ0
46ꢀ5
ALS34H153D2C025
ALS34H223D2L025
ALS34H333D3C025
ALS34H333K2C025
ALS34H473D4C025
ALS34H473K2L025
ALS34H683D5L025
ALS34H683K3C025
ALS34H104K4C025
ALS34H104L3C025
ALS34H154K5L025
ALS34H154L3L025
ALS34H224L5L025
ALS34H224N3L025
ALS34H334N5L025
ALS34H474N8L025
11ꢀ4
13ꢀ5
10ꢀ6
15ꢀ7
13ꢀ2
16ꢀ7
16ꢀ3
19ꢀ6
22ꢀ5
22ꢀ4
25ꢀ4
31ꢀ4
25ꢀ6
33ꢀ2
45ꢀ6
8
6
8
7
76ꢀ2 (3)
76ꢀ2 (3)
6
10000
15000
22000
22000
33000
33000
47000
68000
68000
100000
100000
150000
220000
330000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
54ꢀ0 (2ꢀ125)
142ꢀ9 (5ꢀ625)
66ꢀ7 (2ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
142ꢀ9 (5ꢀ625)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
219ꢀ1 (8ꢀ625)
31
21
16
29
13
20
15
11
10
9
25
17
13
25
11
17
13
10
9
8
7
8
7
9ꢀ2
11ꢀ7
15ꢀ7
17ꢀ7
11ꢀ2
18ꢀ3
13ꢀ9
17ꢀ1
20ꢀ4
23ꢀ6
23ꢀ1
29ꢀ3
25ꢀ5
33ꢀ3
45ꢀ6
ALS34H103D2C040
ALS34H153D3C040
ALS34H223D4C040
ALS34H223K2C040
ALS34H333D5L040
ALS34H333K2L040
ALS34H473K3C040
ALS34H683K4C040
ALS34H683L3C040
ALS34H104K5L040
ALS34H104L4C040
ALS34H154N3L040
ALS34H224N5L040
ALS34H334N8L040
40V dꢀcꢀ
(50V surge)
12ꢀ5
14ꢀ8
10ꢀ0
16ꢀ1
12ꢀ4
15ꢀ5
18ꢀ8
21ꢀ4
21ꢀ7
27ꢀ0
24ꢀ5
32ꢀ2
44ꢀ4
7
9
7
6
76ꢀ2 (3)
76ꢀ2 (3)
6
6800
10000
15000
15000
22000
22000
33000
33000
47000
47000
68000
68000
68000
100000
150000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
54ꢀ0 (2ꢀ125)
142ꢀ9 (5ꢀ625)
66ꢀ7 (2ꢀ625)
79ꢀ4 (3ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
130ꢀ2 (5ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
117ꢀ5 (4ꢀ625)
168ꢀ3 (6ꢀ625)
34
24
17
31
14
21
15
11
12
9
10
7
9
8
6
26
18
14
26
11
18
13
9
10
7
9
7
8
8ꢀ6
11ꢀ7
15ꢀ6
17ꢀ7
11ꢀ4
18ꢀ3
14ꢀ2
17ꢀ3
24ꢀ2
20ꢀ6
27ꢀ1
22ꢀ9
28ꢀ1
27ꢀ0
29ꢀ1
37ꢀ9
ALS34H682D2C050
ALS34H103D3C050
ALS34H153D4C050
ALS34H153K2C050
ALS34H223D5L050
ALS34H223K2L050
ALS34H333K3C050
ALS34H333L3C050
ALS34H473K4C050
ALS34H473L3L050
ALS34H683K5C050
ALS34H683L4C050
ALS34H683N3L050
ALS34H104N4L050
ALS34H154N6L050
50V dꢀcꢀ
(65V surge)
11ꢀ7
14ꢀ1
9ꢀ8
15ꢀ4
12ꢀ2
15ꢀ2
21ꢀ2
18ꢀ5
24ꢀ4
21ꢀ1
26ꢀ0
25ꢀ3
27ꢀ8
36ꢀ6
7
6
Notes: Values of EꢀSꢀRꢀ and Impedance quoted above are maximumꢀ
All dimensions are for the unsleeved capacitorꢀ
22
Cap
(µF)
Nominal Case Size
Maxꢀ ESR (mΩ)
Ripple current
(A) at 85°C
Part number
Rated voltage
dꢀcꢀ
mm (inches)
at 25°C
Dia
Len
120Hz
20kHz
120Hz
20kHz
4700
6800
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
92ꢀ1 (3ꢀ625)
54ꢀ0 (2ꢀ125)
130ꢀ2 (5ꢀ125)
66ꢀ7 (2ꢀ625)
79ꢀ4 (3ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
130ꢀ2 (5ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
104ꢀ8 (4ꢀ125)
168ꢀ3 (6ꢀ625)
37
27
20
32
15
22
16
11
12
9
10
8
9
8
6
27
20
15
26
11
18
13
9
10
7
9
7
8
8ꢀ1
11ꢀ7
13ꢀ8
17ꢀ0
11ꢀ4
18ꢀ4
14ꢀ1
17ꢀ2
24ꢀ5
20ꢀ4
27ꢀ2
22ꢀ7
28ꢀ2
27ꢀ1
28ꢀ0
38ꢀ4
ALS34H472D2C063
ALS34H682D2L063
ALS34H103D3L063
ALS34H103K2C063
ALS34H153D5C063
ALS34H153K2L063
ALS34H223K3C063
ALS34H223L3C063
ALS34H333K4C063
ALS34H333L3L063
ALS34H473K5C063
ALS34H473L4C063
ALS34H473N3L063
ALS34H683N4C063
ALS34H104N6L063
63V dꢀcꢀ
(75V surge)
10ꢀ1
12ꢀ9
9ꢀ5
10000
10000
15000
15000
22000
22000
33000
33000
47000
47000
47000
68000
100000
14ꢀ9
11ꢀ8
14ꢀ7
20ꢀ5
18ꢀ0
23ꢀ8
20ꢀ6
25ꢀ6
25ꢀ0
26ꢀ4
36ꢀ6
7
6
75V dꢀcꢀ
(95V surge)
3300
4700
4700
6800
6800
10000
10000
15000
22000
22000
33000
33000
47000
68000
100000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
66ꢀ7 (2ꢀ625)
117ꢀ5 (4ꢀ625)
79ꢀ4 (3ꢀ125)
92ꢀ1 (3ꢀ625)
117ꢀ5 (4ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
104ꢀ8 (4ꢀ125)
168ꢀ3 (6ꢀ625)
219ꢀ1 (8ꢀ625)
55
40
50
29
34
21
24
21
15
16
11
13
12
9
43
32
42
24
28
17
20
18
14
14
10
12
11
8
7ꢀ1
8ꢀ8
7ꢀ9
9ꢀ4
11ꢀ3
9ꢀ3
ALS34H332D2C075
ALS34H472D2L075
ALS34H472K2C075
ALS34H682D3C075
ALS34H682K2L075
ALS34H103D4L075
ALS34H103K3C075
ALS34H153K3L075
ALS34H223K4L075
ALS34H223L3C075
ALS34H333L4C075
ALS34H333N3L075
ALS34H473N4C075
ALS34H683N6L075
ALS34H104N8L075
10ꢀ6
10ꢀ0
13ꢀ2
12ꢀ6
13ꢀ5
16ꢀ3
16ꢀ6
21ꢀ6
20ꢀ7
21ꢀ9
31ꢀ7
38ꢀ2
13ꢀ2
11ꢀ7
16ꢀ0
14ꢀ6
14ꢀ9
17ꢀ7
18ꢀ0
23ꢀ3
21ꢀ9
22ꢀ9
32ꢀ9
39ꢀ3
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
8
7
2200
3300
3300
4700
6800
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
66ꢀ7 (2ꢀ625)
142ꢀ9 (5ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
104ꢀ8 (4ꢀ125)
168ꢀ3 (6ꢀ625)
219ꢀ1 (8ꢀ625)
61
43
52
31
23
32
18
23
17
16
11
13
12
9
46
33
42
24
18
27
14
20
15
14
10
12
11
8
6ꢀ6
8ꢀ3
7ꢀ7
10ꢀ1
12ꢀ2
9ꢀ5
13ꢀ7
12ꢀ0
15ꢀ0
16ꢀ5
21ꢀ5
20ꢀ8
21ꢀ9
31ꢀ7
38ꢀ4
9ꢀ3
11ꢀ3
9ꢀ3
ALS34H222D2C100
ALS34H332D2L100
ALS34H332K2C100
ALS34H472D3C100
ALS34H682D4C100
ALS34H682K2L100
ALS34H103D5L100
ALS34H103K3C100
ALS34H153K4C100
ALS34H153L3C100
ALS34H223L4C100
ALS34H223N3L100
ALS34H333N4C100
ALS34H473N6L100
ALS34H683N8L100
100V dꢀcꢀ
(125V surge)
13ꢀ2
15ꢀ2
10ꢀ8
16ꢀ4
13ꢀ5
16ꢀ5
18ꢀ3
23ꢀ8
22ꢀ5
23ꢀ1
33ꢀ3
39ꢀ8
6800
10000
10000
15000
15000
22000
22000
33000
47000
68000
76ꢀ2 (3)
8
7
1000
1500
1500
2200
2200
3300
3300
4700
6800
6800
10000
10000
15000
22000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
54ꢀ0 (2ꢀ125)
92ꢀ1 (3ꢀ625)
66ꢀ7 (2ꢀ625)
117ꢀ5 (4ꢀ625)
79ꢀ4 (3ꢀ125)
92ꢀ1 (3ꢀ625)
117ꢀ5 (4ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
104ꢀ8 (4ꢀ125)
142ꢀ9 (5ꢀ625)
149
101
111
70
76
49
52
40
29
29
94
65
74
45
50
32
35
28
21
21
15
16
14
12
4ꢀ1
5ꢀ3
5ꢀ4
7ꢀ0
6ꢀ8
7ꢀ4
9ꢀ2
8ꢀ3
ALS34H102D2C160
ALS34H152D2L160
ALS34H152K2C160
ALS34H222D3L160
ALS34H222K2L160
ALS34H332D4L160
ALS34H332K3C160
ALS34H472K3L160
ALS34H682K4L160
ALS34H682L3C160
ALS34H103L4C160
ALS34H103N3L160
ALS34H153N4C160
ALS34H223N5L160
160V dꢀcꢀ
(200V surge)
11ꢀ9
10ꢀ5
13ꢀ8
13ꢀ1
14ꢀ2
17ꢀ0
17ꢀ4
22ꢀ7
21ꢀ8
22ꢀ8
26ꢀ4
8ꢀ7
8ꢀ7
10ꢀ3
12ꢀ7
13ꢀ1
17ꢀ2
17ꢀ2
19ꢀ2
23ꢀ3
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
20
22
17
15
Notes: Values of EꢀSꢀRꢀ and Impedance quoted above are maximumꢀ
All dimensions are for the unsleeved capacitorꢀ
23
Cap
(µF)
Nominal Case Size
Maxꢀ ESR (mΩ)
Ripple current
(A) at 85°C
Part number
Rated voltage
dꢀcꢀ
mm (inches)
at 25°C
Dia
Len
120Hz
20kHz
120Hz
20kHz
680
1000
1000
1500
1500
2200
2200
3300
4700
4700
6800
6800
10000
15000
22000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
66ꢀ7 (2ꢀ625)
117ꢀ5 (4ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
117ꢀ5 (4ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
104ꢀ8 (4ꢀ125)
142ꢀ9 (5ꢀ625)
168ꢀ3 (6ꢀ625)
241
166
175
112
117
78
81
55
42
42
165
114
123
78
83
55
57
40
3ꢀ4
4ꢀ4
4ꢀ6
5ꢀ6
5ꢀ8
7ꢀ4
7ꢀ5
9ꢀ8
11ꢀ3
11ꢀ7
15ꢀ4
15ꢀ7
17ꢀ8
22ꢀ0
25ꢀ9
5ꢀ9
7ꢀ5
7ꢀ2
9ꢀ3
9ꢀ1
11ꢀ7
11ꢀ5
14ꢀ5
15ꢀ7
16ꢀ1
21ꢀ1
20ꢀ6
22ꢀ1
25ꢀ8
29ꢀ2
ALS34H681D2C200
ALS34H102D2L200
ALS34H102K2C200
ALS34H152D3C200
ALS34H152K2L200
ALS34H222D4L200
ALS34H222K3C200
ALS34H332K4C200
ALS34H472K4L200
ALS34H472L3C200
ALS34H682L4C200
ALS34H682N3L200
ALS34H103N4C200
ALS34H153N5L200
ALS34H223N6L200
200V dꢀcꢀ
(250V surge)
50ꢀ8 (2)
31
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
31
22
23
18
16
29
31
24
19
76ꢀ2 (3)
15
13
250V dꢀcꢀ
(300V surge)
680
1000
1000
1500
1500
2200
2200
3300
4700
4700
6800
6800
10000
15000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
54ꢀ0 (2ꢀ125)
104ꢀ8 (4ꢀ125)
66ꢀ7 (2ꢀ625)
142ꢀ9 (5ꢀ625)
79ꢀ4 (3ꢀ125)
79ꢀ4 (3ꢀ125)
142ꢀ9 (5ꢀ625)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
168ꢀ3 (6ꢀ625)
206
140
154
95
103
67
71
48
36
35
134
91
105
63
70
45
49
33
25
25
18
22
15
13
3ꢀ5
4ꢀ9
4ꢀ7
6ꢀ3
5ꢀ9
6ꢀ3
8ꢀ8
7ꢀ3
10ꢀ9
9ꢀ2
12ꢀ5
11ꢀ7
16ꢀ2
17ꢀ7
19ꢀ0
24ꢀ7
19ꢀ9
26ꢀ9
30ꢀ1
ALS34H681D2C250
ALS34H102D3C250
ALS34H102K2C250
ALS34H152D4C250
ALS34H152K2L250
ALS34H222D5L250
ALS34H222K3C250
ALS34H332L3C250
ALS34H472K5L250
ALS34H472L3L250
ALS34H682L5L250
ALS34H682N3L250
ALS34H103N5L250
ALS34H153N6L250
7ꢀ6
7ꢀ7
10ꢀ8
12ꢀ5
13ꢀ3
17ꢀ7
15ꢀ5
21ꢀ4
25ꢀ4
25
29
20
17
330
470
470
680
680
1000
1000
1500
1500
2200
2200
3300
4700
6800
10000
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
66ꢀ7 (2ꢀ625)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
142ꢀ9 (5ꢀ625)
92ꢀ1 (3ꢀ625)
117ꢀ5 (4ꢀ625)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
142ꢀ9 (5ꢀ625)
168ꢀ3 (6ꢀ625)
366
258
254
180
175
124
120
85
84
58
59
40
230
163
158
114
109
79
75
55
54
38
2ꢀ7
3ꢀ4
3ꢀ7
4ꢀ3
4ꢀ6
5ꢀ5
5ꢀ9
6ꢀ8
7ꢀ5
9ꢀ3
9ꢀ7
12ꢀ9
14ꢀ3
19ꢀ8
23ꢀ9
5ꢀ1
6ꢀ5
6ꢀ7
8ꢀ0
8ꢀ4
10ꢀ0
10ꢀ7
11ꢀ7
12ꢀ4
15ꢀ1
15ꢀ6
20ꢀ3
19ꢀ1
26ꢀ0
29ꢀ7
ALS34H331D2C350
ALS34H471D2L350
ALS34H471K2C350
ALS34H681D3C350
ALS34H681K2L350
ALS34H102D4C350
ALS34H102K3C350
ALS34H152D5L350
ALS34H152K3L350
ALS34H222K4L350
ALS34H222L3C350
ALS34H332L4C350
ALS34H472N3L350
ALS34H682N5L350
ALS34H103N6L350
350V dꢀcꢀ
(400V surge)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
38
26
25
18
35
25
19
14
330
470
470
680
680
1000
1000
1500
1500
2200
2200
3300
3300
4700
6800
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
54ꢀ0 (2ꢀ125)
104ꢀ8 (4ꢀ125)
66ꢀ7 (2ꢀ625)
130ꢀ2 (5ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
130ꢀ2 (5ꢀ125)
92ꢀ1 (3ꢀ625)
117ꢀ5 (4ꢀ625)
92ꢀ1 (3ꢀ625)
130ꢀ2 (5ꢀ125)
142ꢀ9 (5ꢀ625)
355
249
262
174
181
120
124
84
83
60
59
41
227
159
171
111
118
78
81
56
55
40
2ꢀ7
3ꢀ7
3ꢀ7
4ꢀ8
4ꢀ6
5ꢀ8
6ꢀ0
7ꢀ9
8ꢀ5
10ꢀ0
10ꢀ8
13ꢀ4
13ꢀ3
17ꢀ3
20ꢀ1
5ꢀ2
7ꢀ2
6ꢀ5
8ꢀ9
8ꢀ1
10ꢀ5
10ꢀ4
13ꢀ2
14ꢀ5
15ꢀ9
17ꢀ5
20ꢀ4
19ꢀ1
23ꢀ6
26ꢀ2
ALS34H331D2C400
ALS34H471D3C400
ALS34H471K2C400
ALS34H681D4C400
ALS34H681K2L400
ALS34H102D5C400
ALS34H102K3C400
ALS34H152K4C400
ALS34H152L3C400
ALS34H222K5C400
ALS34H222L3L400
ALS34H332L4L400
ALS34H332N3L400
ALS34H472N5C400
ALS34H682N5L400
400V dꢀcꢀ
(450V surge)
39
28
30
23
43
32
22
76ꢀ2 (3)
76ꢀ2 (3)
16
Notes: Values of EꢀSꢀRꢀ and Impedance quoted above are maximumꢀ
All dimensions are for the unsleeved capacitorꢀ
24
Cap
(µF)
Nominal Case Size
Maxꢀ ESR (mΩ)
Ripple current
(A) at 85°C
Part number
Rated voltage
dꢀcꢀ
mm (inches)
at 25°C
Dia
Len
120Hz
20kHz
120Hz
20kHz
220
330
330
470
470
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
79ꢀ4 (3ꢀ125)
54ꢀ0 (2ꢀ125)
92ꢀ1 (3ꢀ625)
66ꢀ7 (2ꢀ625)
130ꢀ2 (5ꢀ125)
79ꢀ4 (3ꢀ125)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
130ꢀ2 (5ꢀ125)
92ꢀ1 (3ꢀ625)
92ꢀ1 (3ꢀ625)
104ꢀ8 (4ꢀ125)
142ꢀ9 (5ꢀ625)
168ꢀ3 (6ꢀ625)
398
266
279
189
195
132
136
94
93
65
64
47
243
163
175
116
122
82
85
59
58
42
2ꢀ5
3ꢀ5
3ꢀ5
4ꢀ4
4ꢀ4
5ꢀ4
5ꢀ6
7ꢀ4
8ꢀ0
5ꢀ1
7ꢀ1
6ꢀ4
8ꢀ6
8ꢀ0
10ꢀ3
10ꢀ2
13ꢀ0
14ꢀ3
15ꢀ8
17ꢀ4
19ꢀ2
20ꢀ8
24ꢀ8
29ꢀ1
ALS34H221D2C450
ALS34H331D3C450
ALS34H331K2C450
ALS34H471D3L450
ALS34H471K2L450
ALS34H681D5C450
ALS34H681K3C450
ALS34H102K4C450
ALS34H102L3C450
ALS34H152K5C450
ALS34H152L3L450
ALS34H222N3L450
ALS34H332N4C450
ALS34H472N5L450
ALS34H682N6L450
450V dꢀcꢀ
(500V surge)
680
680
1000
1000
1500
1500
2200
3300
4700
6800
9ꢀ5
41
31
24
20
10ꢀ2
12ꢀ7
14ꢀ8
18ꢀ8
22ꢀ5
34
27
23
76ꢀ2 (3)
17
500V dꢀcꢀ
(550V surge)
150
220
330
330
470
470
680
680
1000
1000
1500
1500
2200
3300
4700
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
34ꢀ9 (1ꢀ375)
50ꢀ8 (2)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
50ꢀ8 (2)
63ꢀ5 (2ꢀ5)
63ꢀ5 (2ꢀ5)
76ꢀ2 (3)
76ꢀ2 (3)
76ꢀ2 (3)
54ꢀ0 (2ꢀ125)
66ꢀ7 (2ꢀ625)
92ꢀ1 (3ꢀ625)
54ꢀ0 (2ꢀ125)
117ꢀ5 (4ꢀ625)
66ꢀ7 (2ꢀ625)
104ꢀ8 (4ꢀ125)
79ꢀ4 (3ꢀ125)
130ꢀ2 (5ꢀ125)
92ꢀ1 (3ꢀ625)
104ꢀ8 (4ꢀ125)
92ꢀ1 (3ꢀ625)
117ꢀ5 (4ꢀ625)
168ꢀ3 (6ꢀ625)
219ꢀ1 (8ꢀ625)
732
501
335
273
237
191
174
173
90
119
82
83
59
41
547
375
251
188
178
131
133
132
62
91
63
65
46
2ꢀ2
2ꢀ8
3ꢀ8
3ꢀ7
4ꢀ7
4ꢀ6
6ꢀ3
6ꢀ8
8ꢀ6
3ꢀ7
4ꢀ8
6ꢀ4
6ꢀ1
7ꢀ8
ALS34H151D2C500
ALS34H221D2L500
ALS34H331D3L500
ALS34H331K2C500
ALS34H471D4L500
ALS34H471K2L500
ALS34H681K4C500
ALS34H681L3C500
ALS34H102K5C500
ALS34H102L3L500
ALS34H152L4C500
ALS34H152N3L500
ALS34H222N4L500
ALS34H332N6L500
ALS34H472N8L500
7ꢀ7
10ꢀ0
10ꢀ9
14ꢀ4
13ꢀ6
15ꢀ9
16ꢀ2
19ꢀ1
26ꢀ7
34ꢀ7
8ꢀ7
10ꢀ7
11ꢀ1
13ꢀ7
19ꢀ8
26ꢀ4
32
18
76ꢀ2 (3)
24
Notes: Values of EꢀSꢀRꢀ and Impedance quoted above are maximumꢀ
All dimensions are for the unsleeved capacitorꢀ
25
DIMENSIONS mm MATERIAL Zinc plated steel
Horizontal Mounting
TYPE
CAN
DIA
A
B
C
F
H1
H2
25ꢀ0
35ꢀ0
40ꢀ0
52ꢀ0
22ꢀ3
22ꢀ3
12ꢀ8
12ꢀ8
10ꢀ0
10ꢀ0
Vertical Mounting
TYPE
CAN
DIA
A
B
C
F
V2
V3
V9
25ꢀ0
35ꢀ0
40ꢀ0
49ꢀ0
58ꢀ0
65ꢀ0
19ꢀ0
19ꢀ0
19ꢀ0
37ꢀ0
45ꢀ0
52ꢀ4
10ꢀ0
9ꢀ0
9ꢀ5
TYPE
CAN
A
B
C
E
F
DIA
51ꢀ0
45ꢀ0
63ꢀ5
V4
V6
V8
75ꢀ0
69ꢀ5
88ꢀ9
25ꢀ4
17ꢀ4
25ꢀ4
64ꢀ0
58ꢀ0
77ꢀ5
5ꢀ0
4ꢀ0
5ꢀ0
10ꢀ0
10ꢀ0
9ꢀ5
TYPE
CAN
DIA
A
B
C
D
F
UTE2736 35ꢀ0
63ꢀ0
12ꢀ2
54ꢀ0
17ꢀ2
9ꢀ0
TYPE
CAN
DIA
A
B
C
D
E
F
V10
V11
V90
65ꢀ0
90ꢀ0
40ꢀ0
30ꢀ0 5ꢀ0 4ꢀ5
30ꢀ0 5ꢀ0 4ꢀ5
30ꢀ0 5ꢀ0 4ꢀ5
-
-
-
76ꢀ0 103ꢀ0 45ꢀ5
90ꢀ0 116ꢀ0 53ꢀ5
UTE2737 50ꢀ0
UTE2738 65ꢀ0
UTE2739 72ꢀ0
75ꢀ5
88ꢀ5
97ꢀ0
33ꢀ5
39ꢀ0
44ꢀ0
27ꢀ0 4ꢀ3 4ꢀ3 39ꢀ5
27ꢀ0 4ꢀ3 4ꢀ3 45ꢀ0
28ꢀ0 4ꢀ3 4ꢀ3 50ꢀ0
Note
When using mounting clamps care should be taken not to
obscure any safety vent in the canꢀ
26
INSULATED VERSION
M8 Stud (M12 Stud)
NON-INSULATED VERSION
M8 Stud (M12 Stud)
Dimensions mmꢀ All the above accessories may be ordered individually using the part number shown, or as kits using the kit
part numbers shown belowꢀ
Kit Contents and Ordering Information
STANDARD KITS
Kit order number
2741
-
-
-
●
-
●
Part code
2352
2353
2772
2773
2778
2779
2788
Description
2740
-
-
●
-
●
-
-
2782
2785
Steel washer M8
Steel washer M12
Stepped poly washer M8
Stepped poly washer M12
Plain poly washer M8
Plain poly washer M12
Steel nut M12
●
-
-
●
-
-
-
-
-
-
-
-
-
-
●
2789
Steel nut M8
-
-
●
-
2792
2793
Kit description
Nylon nut M8
Nylon nut M12
●
-
-
●
-
-
-
-
Non-insulated
M8
Insulated
M8
Insulated
M12
Non-insulated
M12
SPECIAL KITS
Kit order number
Part code
2352
2353
2772
2773
2778
2779
2788
2789
2728
2734
Description
2684
-
-
●
-
-
-
-
●
-
-
2685
-
-
-
●
-
-
●
-
-
-
2690
2691
-
-
●
-
●
-
-
●
-
2692
●
-
●
-
●
-
-
●
-
2693
2695
-
-
-
●
-
●
●
-
-
-
Steel washer M8
Steel washer M12
Stepped poly washer M8
Stepped poly washer M12
Plain poly washer M8
Plain poly washer M12
Steel nut M12
Steel nut M8
Nylon nut M12
Nylon nut M12
-
●
-
●
-
-
●
-
-
●
-
●
-
●
●
-
-
-
-
-
-
-
27
SCREW TERMINAL CAPACITORS
ALS34/35
AL
S
34
H
472
N
5L
450
ALUMINIUM ELECTROLYTIC
SCREW TERMINAL
RANGE MOUNTING STYLE (34 = Plain Can, 35 = Stud Mounting)
TERMINATION STYLE (H = 10-32 UNF class2B) see terminal options on page 16
CAPACITANCE µF (first two digits equals first two significant figures;
third digit is number of zeros following egꢀ 472 = 4,700µF)
CAN DIAMETER (see page 17)
CAN LENGTH (see page 17)
RATED VOLTAGE dꢀcꢀ
Capacitor marking
The capacitors are marked with items as a minimumꢀ
1& Rated capacitance in µF
2& Rated voltage dꢀcꢀ
3& Polarity of terminations
4& Tolerance on rated capacitance
5& Date code/Batch number
6& BHC part number
Included for your reference is the Ordering Information for
the complete BHC range of Electrolytic Aluminium
Capacitorsꢀ
SCREW TERMINAL CAPACITORS
ALS30/31, ALS40/41
AL
S
30
A
682
RP
350
ALUMINIUM ELECTROLYTIC
SCREW TERMINAL
RANGE MOUNTING STYLE 30, 40 plain can 31, 41 stud can
TERMINATION STYLE A,B,C,F,G,J,M or R
CAPACITANCE µF (first two digits equals first two significant figures;
third digit is number of zeros following egꢀ 682 = 6,800µF)
CASE SIZE (code)
RATED VOLTAGE dꢀcꢀ
SNAP-IN CAPACITORS
ALC10, ALC40
ALC12, ALC42
AL
C
10
A
272
AB
040
ALUMINIUM ELECTROLYTIC
SNAP-IN
RANGE 10, 40, 12, 42
TERMINATION STYLE Long pin (6ꢀ3mm): A=2 Pin, C=4 pin, G=5 pin
Short pin (4ꢀ0mm): D=2 pin, E=4 pin, F=3 pin, H=5 pin
CAPACITANCE µF
(first two digits equals first two significant figures;
third digit is number of zeros following egꢀ 272 = 2,700µF)
CASE SIZE (code)
RATED VOLTAGE dꢀcꢀ
28
PCB & SOLDER TAG CAPACITORS
ALP10/20/22, ALT10/11/20/21/22/23
AL
P
10A
223
DF
350
ALUMINIUM ELECTROLYTIC
TERMINATION STYLE T=Tag, P=Pin
RANGE MOUNTING STYLE 10A, 20A, 22A plain can
11A, 21A, 23A stud can (stud only available on ALT series)
CAPACITANCE µF
(first two digits equals first two significant figures;
third digit is number of zeros following egꢀ 223 = 22,000µF)
CASE SIZE (code)
RATED VOLTAGE dꢀcꢀ
SPECIAL PART NUMBERS
Used when the design is different in any way from the data listed
for a standard itemꢀ This can include anything from special
electrical parameters to special print detailꢀ
AL
S
30
A
1001
MF
ALUMINIUM ELECTROLYTIC
TYPE IꢀEꢀ SCREW TERMINAL
RANGE AND MOUNTING STYLE
TERMINATION STYLE
SEQUENTIAL NUMBER UNIQUE TO DESIGN
CASE CODE (code)
SAMPLE PART NUMBERS
The sample part number is used when a design has been raised as a
feasibility, with or without samples being madeꢀ A full part number
is issued, either as a standard or special design, once the item goes
to full productionꢀ
NS
4
B
/
123
NON STANDARD
RANGE
STYLE
SEQUENTIAL NUMBER UNIQUE TO DESIGN
29
To:
Company:
Fax:
Email:
Date:
Page (s):
Sales Department
BHC Components
+44 1305 760 670
bhcsales@bhc.co.uk
Design Request
Customer Details
Contact Name:
Company:
Department:
Phone:
Reply Required by:
Potential (pcs/year):
Currently Using:
Ext. Number:
Fax:
Email:
Product Details
Item 1
Item 2
Item 3
Type:
Capacitance (µF):
Tolerance (±%):
Voltage (v):
Can Size:
Plain / Stud Can:
Terminals:
Temp Range (°C):
Additonal Notes
Operating Conditions
i.e. ripple current, life
required, temperature
BHC Components Ltd.,
20 Cumberland Drive,
Granby Industrial Estate,
Weymouth,
Dorset DT4 9TE
United Kingdom
Telephone +44 (0)1305 782871
Fax
+44 (0)1305 760670
bhcsales@bhc.co.uk
Email
Web site www.bhc.co.uk
12/02
© BHC Components Ltd.
Design - creations@panpublicity.co.uk
相关型号:
ALS35H153D4C050
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 50V, 30% +Tol, 10% -Tol, 15000uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H153D5C063
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 63V, 30% +Tol, 10% -Tol, 15000uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H222D4L200
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 200V, 30% +Tol, 10% -Tol, 2200uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H222K3C200
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 200V, 30% +Tol, 10% -Tol, 2200uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H222K3C250
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 250V, 30% +Tol, 10% -Tol, 2200uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H223D4C040
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 40V, 30% +Tol, 10% -Tol, 22000uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H223N3L100
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 100V, 30% +Tol, 10% -Tol, 22000uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H223N5L160
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 160V, 30% +Tol, 10% -Tol, 22000uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H223N6L200
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 200V, 30% +Tol, 10% -Tol, 22000uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H224L3L016
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 16V, 30% +Tol, 10% -Tol, 220000uF, Chassis Mount, RADIAL LEADED
KEMET
ALS35H332K3C160
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 160V, 30% +Tol, 10% -Tol, 3300uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
ALS35H332K4C200
Aluminum Electrolytic Capacitor, Polarized, Aluminum (wet), 200V, 30% +Tol, 10% -Tol, 3300uF, Stud Mount, CAN, ROHS COMPLIANT
KEMET
©2020 ICPDF网 联系我们和版权申明