CS28B0937 - Leader Tech - Datasheet.Live

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• World’s Largest In-Stock Selection

• Frequency-Specific Formulations

• Flexible Mounting Options

The Leading Edge in EMI Shielding Technology

BISECTED & SOLID BEAD STYLES

FOR ROUND AND FLAT CABLES & WIRES

FerriShield FerriteS

Shielded enclosures, even the most robust designs, will permit

electromagnetic energy to enter or exit along the main cabling. FerriShield

Ferrites are one of the most versatile and cost-effective cable shielding

methods available today. Our ferrites attack unwanted RF right on the circuit

wiring, eliminating the need for more costly forms of RFI control. Available

in solid and bisected designs, each style can make the task of regulatory

compliance quicker and less troublesome.

Our bisected styles use FerriShield’s innovative, quick-snap clamshell

enclosures. This unique design concept offers engineers the ultimate in

adaptability and easy installation. The RF absorbing core material interacts

directly with unwanted high-frequency energy and dissipates it effectively

while allowing data signals to pass unimpeded.

Welcome to FerriShield

For more than 25 years, FerriShield ferrites have been the preferred cable

shielding solution for many of the world’s leading EMI Shielding Distributors,

Sales Representatives and OEM’s. Since acquiring the company in 2006,

Leader Tech has embraced the FerriShield philosophy of maintaining the

world’s largest in-stock selection of bisected and solid core ferrites.

The addition of cable mounted ferrites to Leader Tech’s existing EMI shielding

product line has signiﬁcantly increased value for our customers. Backed

by unparalleled service and engineering support, Leader Tech now offers

the market’s most reliable selection of board, enclosure and cable shielding

solutions.

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table of contents

ferrites for flat and round cables RFID shielding

testing aids

electrical and mechanical specifications

installation, ordering, part # reference

Universal Wideband Material (28 Material)

10 cable snaps

for round cables

12 sleeve snaps

for round cables

13 USB cable sleeve snap

with universal variable diameter

14 cable bundle clamps

for wire and cable groups

14 telecom cable snaps

for flat-oval cables

15 solid beads and toroids

for round cables

15 extra large toroids

up to 6.66” inside diameter

16 flat cable clamps

for flat cables and flex circuits

16 low profile flat cable clamps

for flat cables and flex-circuits

19 low profile solids

for flat cables and flex-circuits

19 rectangular solids

for flat cables and flex circuits

21 universal wideband bus bar ferrites

extra large openings for most sizes

Low-Frequency Material (33 Material)

22 low frequency cable snaps

for round cables

23 low frequency cable clamps

for flat cables and flex circuits

High-Frequency Material (25 Material)

24 high frequency cable snaps

for round cables

25 high frequency cable clamps

for flat cables and flex circuits

Bluetooth/Microwave Material (20 Material)

26 bluetooth/microwave cable snaps

for round cables

27 bluetooth/microwave cable clamps

for flat cables

28 RFID overview

13.56, 433.32, 860-930 MHz; 2.45 & 5.8 GHz

29 frequency-specific ferrites

13.56, 433.32, 860-930 MHz; 2.45 & 5.8 GHz

7 insertion loss formula

simple engineering calculation model

9 technical information

for specifying products

32 attenuation by part number

impedance performance by frequency

33 material properties

typical performance characteristics

33 cable size by part number

recommended cable sizes

30 engineering kits and test equipment

test fixtures, test probes

34 test probes

electric and magnetic near-field detectors

35 installation guidelines for ferrites

cable size, positioning, attachment options

36 all part numbers by page number

all catalog items in stock at all times

39 ordering

general information, customer samples,

ISO 9001:2008 Quality System Registration, RoHS

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ISO 9001: 2008

CERTIFIED

✔

RoHS

COMPLIANT

FerriShield Ferrites

Simply one of the most flexible

and cost-effective cable shielding

solutions on the market

4 Frequency-Specific Ferrite Formulations

• 28 Material Wideband Ferrite (Most Popular)

• 33 Material Low-Frequency Ferrite

• 25 Material High-Frequency Ferrite

• 20 Material Bluetooth/Microwave Ferrite

1,000s of Styles and Sizes

• Solid and Bisected Styles

• I.D.’s from .034” to 6.6”

• Round, Square & Flat Shapes

• Special application designs

10 Flexible, Quick Mounting Options

Integrated Mounting Options:

• Snug Cable-Fit

• Button Mount

• Adhesive Mount

• Screw Mount

• Flexible-Grip End Ports

2-Piece Mounting Options:

• Cable Tie Base

• Press Fit Base

• Adhesive Mount Base

• Screw Mount Base

• Screw Mount Strap

www.leadertechinc.com

ISO 9001:2008 registered

PRODUCT OVERVIEW:

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HOW TO select a FerriShield Ferrite for your application

Choose a ferrite material

FerriShield ferrites are offered in (4) unique formulations. The chart below offers an overview

of typical material properties and catalog page references.

Ferrite Performance Catalog Pages

28 Material- Most Popular Wideband 10MHz-1GHz (250MHz peak) 10 to 21

33 Material- Low-Frequency Ferrite 1MHz-60MHz (30MHz peak) 22 to 23

25 Material- High-Frequency Ferrite 1MHz-1.2GHz (700MHz peak) 24 to 25

20 Material- Bluetooth/Microwave 2.45GHz peak 26 to 27

For detailed Attenuation and Material Properties see page 32 and 33

Select a mounting option

Each section of this catalog features multiple mounting options for bisected and solid

bead ferrites. FerriShield Ferrites are recognized for their ease of installation and reliable

performance over time.

Select the inside diameter of your ferrite

FerriShield Ferrites are designed to t tight against the cable or wiring bundle that requires

shielding. Ideally, you should select a ferrite with an inside diameter that is slightly less

(+/- .04”) than the outside diameter of your cable.

For quick reference, all part numbers in this catalog have an accompanying technical drawing

and specications chart that illustrates dimensions and impedance for the selected ferrite.

For a more detailed technical explanation see page 33.

1

2

3

• Ferrite performance typically increases as ferrite volume increases. The larger the

ferrite mass, the better the RF attenuation.

• Smaller cables can be looped through larger ferrites to increase performance.

Impedance increase by the square of the number of loops. For example, by

looping a cable through a ferrite 2 times (22), impedance increases by a factor of 4.

For a detailed explanation see page 6- Electromagnetic Characteristics

• Ferrite installation guidelines and recommendations are shown on page 35

• Attenuation properties by part number can be referenced on page 32

• Maximum recommend cable size by part number can be found on page 33

Helpful Tips and Insider Hints

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a powerful insertion loss device

Ferrite shielding materials are widely accepted as providing

the simplest, most convenient and most cost-effective solution

for radio frequency interference problems in cables and

connectors. Further, they accomplish both RF attenuation

and suppression of unwanted high frequency oscillations

with no loss in dc or low frequency signal strength.

The basic composition of ferrite materials is a combination

of ferrous oxide and one or more other powdered metals -

most often manganese, zinc, cobalt or nickel. An extensive

selection of shapes and sizes is already available, and custom

geometries may be manufactured for special situations.

There are innite varieties of formulas and performance

levels possible. Each discrete ferrite formulation results in

a stoichiometric ratio which is its performance characteristic

signature regarding electrical, magnetic and mechanical

relationships. The most common expression of ferrites’

performance capabilities is in terms of their permeability

(µ). This property expresses the ratio of the magnitude of

magnetic induction to magnetizing force. The materials are

normally categorized according to initial permeability (µi).

FerriShield has developed four principal formulations

which together serve the common spectrum of today’s

RFI needs. For frequencies from 10 MHz to 1 GHz,

#28 formulation is recommended, especially when higher

frequency harmonics are a consideration. For frequencies

typied by microprocessor speeds in excess of 100MHz

and harmonics peak interference at nominally 700MHz, #25

formulation is designed to cover this range with even some

effect beyond that. For frequencies from 1 MHz to 30 MHz,

#33 material offers a concentration of impedance in that

range with a decreasing effect above 30 MHz. For microwave

frequencies relating to Bluetooth™ 2.45GHz operations, the

#20 material is available. See gure 1 above.

Stated most simply, the operative characteristic which

makes ferrites effective in RFI/EMI suppression is their

variable sensitivity to frequency. With a ferrite installed as a

suppressor, lower frequencies will pass with no signicant

loss. But above the frequency where (tan d/µ) climbs sharply

(see gure 1), the signal couples with the ferrite to create

an impedance which is quite high compared with the rest

of the circuit. The offending RFI is thus immediately and

consistently blocked out by way of impedance damping

of the unwanted high frequency signals. It is this greater

resistive impedance which allows the basically passive,

apparently simple material to suppress multiple signals in a

variety of application situations.

Electromagnetic Characteristics

ﬁg. 3

Two turn loop through

ferrite increases

effective magnetic

path. Impedance

increases by the square

of the number of turns

(N2).

ﬁg. 2

Impedance comparison

vs. cubic volume.

ﬁg. 4

Increased impedance;

multiple turns (N2)

vs. one turn through

ferrite; i.e., 2 turns

(22) = 4 times

impedance

TYPICAL PERFORMANCE

FREQUENCY (Hz)

1M 10M 100M 1G

1000

100

10

1

850 Permeability ( i)

#28 Ferrite (Popular,

universal formula)

125 Permeability ( i)

#25 Ferrite (Specific,

high-frequency formula)

20 Permeability ( i)

#20 Ferrite (Microwave

formula)

2700 Permeability ( i)

#33 Ferrite (Specific,

low-frequency formula)

ﬁg. 1 Typical attenuation proles

BA

C

Product Profile

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a powerful insertion loss device

To understand the various practical modeling techniques

employed with ferrite, it is best to prepare a properly engineered

calculation of expected results. An empirical trial and error

method may leave the circuit close to borderline performance

without adequate safety margins. As indicated previously, a

wide range of formulations is possible. The major application

factors to be used when dening a specic ferrite solution for a

particular interference problem include the following:

- Frequency where maximum attenuation is required.

- Amount of attenuation needed.

- Ferrite permeability formulation characteristics as they

relate to the frequency range in question (i.e., initial

permeability)

- Ferrite formulation consistency (i.e., expected range of

variation in attenuation performance)

- Installation environment and mechanical attachment

requirements.

The frequency range requiring attenuation must be matched

to the performance of a given ferrite composition (gure 1

on previous page). The optimum prole would be a ferrite

in which the highest attenuation level coincides with the

disruptive frequency (A). That same ferrite could be used even

if the frequency falls in a lower area of its impedance curve

(B) but there would be correspondingly reduced attenuation.

Conversely, a different ferrite formulation could be employed

in the same frequency situation with the intent of using a

lower part of its performance curve (C). Space and weight

considerations are not normally a concern since good quality

ferrites provide high performance per a given cubic volume.

The modeling procedure to calculate impedance

characteristics of the source and load coupled with the ferrite

suppressor is developed as follows:

Insertion 20 log10 (ZA + ZB + ZF)

Loss (dB) (ZA + ZB)

Where:

Insertion Loss = A measure of the effectiveness of

a lter, expressed in decibels, is described as the

ratio of voltages with, and without, the lter in

the circuit.

ZA = Source Impedance

ZB = Load Impedance

ZF = Ferrite Impedance

If the circuit impedance (ZA + ZB) is 50 ohms and the ferrite

impedance is 250 ohms, then the insertion loss will be:

20 Log10 (50+250)/50 = 15.56 dB

Even though the same unit of ferrite is used, the attenuation

provided by a ferrite suppressor can differ somewhat as the

original circuit impedance varies. The ferrite is more effective

when the circuit impedance is low. For example, by using the

same 250 ohm ferrite in a 75 ohm circuit, the result will be:

20 Log10 (75 + 250)/75 = 12.7 dB

With a high circuit impedance, it may be possible to increase

the number of turns or passes through the ferrite (gures 3

and 4), or to use a larger amount of ferrite (cubic volume) in the

circuit in order to achieve the same level of insertion loss (g. 2).

By increasing the number of turns (passes) through the ferrite

opening, the “effective magnetic path” is increased _ impedance

then increases by the square of the number of turns (N2) ; i.e.,

two turns (22) = 4 times the impedance. When additional ferrite

volume is added, impedance increases on almost a direct

percentage basis; i.e., a 100 percent increase in volume will

provide about 100 percent increase in impedance (gure 2)

in most situations according to certain prescribed dimensional

ratios.

An alternative modeling procedure may also be structured in

reverse by solving for a desired insertion loss goal. The result

yields an impedance requirement. This can be matched to

known performance proles of existing ferrite congurations in

the geometric style best suited for mechanical and packaging

requirements.

As an example, a 15dB insertion loss is required for a at ribbon

cable at 100 MHz. Using the formula:

Insertion Loss (dB) = 20 log10 (ZA + ZB + ZF)

(ZA + ZB)

Where: IL = 15 dB

ZA = 25 ohms

ZB = 25 ohms

ZF = Unknown ferrite impedance

(solve for this value)

15dB = 20 Log10 50 + ZF

25 + 25

0.75 = Log10 50 + ZF

50

5.625 = 50 + ZF

50

ZF = 231.25 ohms

Next, refer to the Attenuation Properties on page 36. The at

ribbon cable style part that closely matches is #28B2480 with a

250½ impedance at 100 MHz.

Once the ferrite suppressor is installed in the circuit, results

should be conrmed by testing. Although these ferrites are

“linear,” the term is relative to the common operating range of

temperatures. The permeability is different at every degree of

temperature. The published initial permeability (µi) nomenclature

applies to standard temperature, 59°F (15°C) only. There are

only minor impedance differences, however, throughout normal

operational ranges and up to 180° F (82°C). See Material

Properties on page 33.

=

Organizing the Engineering Model

(

()

)

7

ferrites for interference control

SHIELDING EFFECTIVENESS (dB)

PERCENT ATTENUATION

ATTENUATION RATIO

020406080 100 120

99.9999

99.999

99.99

99.9

99.0

90.0

1,000,000:1

100,000:1

10,000:1

1,000:1

100:1

10:1

Any device used to block an RFI signal between its source

and a receiver is an electromagnetic interference (EMI) shield.

The measure of this ability to attenuate RFI is Shielding

Effectiveness, SE, which is expressed in decibels, dB, the ratio

of eld strength on one side of the shield to the other side.

The gure above shows the relationship between shielding

effectiveness (in dB), the amount of attenuation, and attenuation

percentage.

The concept of bisected ferrites has been developed

to address a number of industry needs in the area of

Electromagnetic Compatibility, EMC.

• engineering adaptability

• risk-free engineering:

- tight tolerance performance

- easy to upgrade attenuation by changing size or

number of turns.

• easy retrotting

• convenient installation

• integral mounting features

• cost-effectiveness

• extended resistance to core saturation under Direct

Current loads.

• consistent performance

Engineering assistance is always available. We will be

pleased to help with applications, cross-referencing or complete

insertion loss calculations when a custom suppressor is

required.

Design Support

FerriShield Advantages

Typical FerriShield RFI suppressor.

I/O cable with RFI suppressor.

UL recognized

plastic case

Bisected ferrite

RFI absorber

Cable gripping

entry/exit port

The technical air gap in bisected ferrites actually extends

current carrying capability with only an imperceptible

reduction in impedance versus solid ferrites of the

same size. The gap is magnetically insignicant while

it is electrically signicant as a discontinuation, thereby

accommodating more current.

Gap effect of ferrite subjected to direct current.

Controlling RFI/EMI

For attenuation properties by frequency, see page 32 8

AA

C

B

Advantages

Electronic cabling and wires, by virtue of their length-to-width ratios, are perfect natural antennas. In the

presence of high speed microprocessor signals, cables will conduct, radiate and/or receive unwanted high frequency

interfering signals. Control of radio frequency interference can be assured by proper placement of an insertion loss

device, such as a ferrite suppressor.

Compared to other alternatives, ferrites’ high resistivity per

cubic volume stands out as the most important advantage. Prior

to the development of bisected ferrites, suppression engineering

was restricted to the costly addition of lters, cable shielding,

and less versatile solid core (not bisected) ferrites. While these

methods offer a degree of suppression, they are often awkward to

install and, in many cases, are not completely effective. Bisected

ferrites have a concentrated, homogeneous magnetic structure

with high permeability. They are consistently stable versus time

and temperature, and provide RF suppression without high eddy

current losses.

Anywhere There is an Antenna-Like Structure

Application Points

FerriShield installation locations.

A. Data signals and high frequency interference signals

absorbed and conducted

B. All high frequency interference absorbed by ferrite

suppressor and thermally dissipated

C. Low frequency data signals pass unimpeded

Just snap over circuit wiring to be controlled - even after wiring has been terminated Radio interference sources

usually radiate their RFI power at frequencies above 30 MHz by way of the main cabling, which acts as an antenna.

Installation is simple

CABLING

RFI suppressor functions

BUS BARS

RFI suppressor functions: bus bars

ferrites for interference control

A. Power distribution and high frequency interference

signals absorbed and conducted

B. All high frequency interference absorbed by ferrite

suppressor and thermally dissipated

C. Power distribution characteristics pass unimpeded

For attenuation properties by frequency, see page 32 9

For attenuation properties by frequency, see page 32

28 material wideband ferrites- up to 1GHz applications

A

D

E

C

F

B

Ferrite assembly in fully enclosed nylon case; functional with wires and

cables up to a 2.0” (50,8mm) diameter. Snap closed around wire by

clasping shut to position assembly.

May also be mounted with a at-head screw through the .120” (3,0mm)

diameter hole in the bottom by temporarily removing lower ferrite half.

WITH ADHESIVE MOUNT BASE. Ferrite assembly in fully enclosed

nylon case; various sizes are functional with wires and cables up to a

1.0” (25,4mm) diameter. After closing around wire and clasping shut,

assembly is ready for mounting. Installs by removing protective paper

strip from base and pressing into place.

WITH SCREW MOUNT BASE. Ferrite assembly in fully enclosed

nylon case; various sizes are functional with wires and cables up to a

1.0” (25,4mm) diameter. Mounting base press-ts into receptacle on

bottom. Installs at the intended location with a screw through the .125”

(3,2 mm) diameter hole provided. The base may be positioned at 90º

increments relative to the upper case to provide four alternative assembly

congurations.

WITH VARIABLE DIAMETER END PORTS. Ferrite assembly in fully

enclosed nylon case; various sizes are functional with wires and cables

up to a .500 (12,7 mm) diameter. End ports are surrounded with exible

spring utes to grip a range of cable diameters from .120” to .500” (3,2 to

12,7 mm). The grip-locking action prevents lateral movement along the

cable or wire bundle.

WITH PRESS-FIT BUTTON MOUNT BASE. Ferrite assembly in fully

enclosed nylon case; functional with wires and cables up to a 1.0”

(25,4mm) diameter. Includes a button mount base which press-ts into a

.150” (3,8mm) diameter hole.

A

D

CB

A

D

C

.070 (1,8)

.110(2,8).168(4,3)

B

.150(3,8)

A

D

CB

EF

Adhesive Pad

A

D

CB

EF

(Screw not included)

PART No. A B C D

IMPEDANCE IN OHMS

CS28B1642 .852 21,6 .885 22,5 .840 21,3 .282 7,2 100 @ 100MHz

CS28B1805 1.040 26,4 .667 16,9 1.025 26,4 .340 8,6 73 @ 100MHz

CS28B1937 1.182 30,0 .780 19,8 1.188 30,2 .425 10,8 117 @ 100MHz

CS28B1984 1.218 30,9 .705 17,9 1.220 31,0 .525 13,3 62 @ 100MHz

CS28B1501 1.725 43,8 1.232 31,3 1.720 43,7 .710 18,0 177 @ 100MHz

CS28B1500 1.725 43,8 1.232 31,3 1.720 43,7 .960 24,4 133 @ 100MHz

CS28B2000 2.350 59,7 1.851 47,0 2.309 58,6 .960 24,4 See page 31 for more details 380 @ 100MHz

CS28B4000 4.500 114,2 1.851 47,0 4.687 119,0 1.960 49,8 See page 31 for more details 290 @ 100MHz

PART No. A B C D

IMPEDANCE IN OHMS

CF28B1642 .852 21,6 .885 22,5 .840 21,3 .282 7,2 100 @ 100MHz

CF28B1805 1.040 26,4 .667 16,9 1.025 26,4 .340 8,6 73 @ 100MHz

CF28B1937 1.182 30,0 .780 19,8 1.188 30,2 .425 10,8 117 @ 100MHz

CF28B1984 1.218 30,9 .705 17,9 1.220 31,0 .525 13,3 62 @ 100MHz

CF28B1501 1.725 43,8 1.232 31,3 1.720 43,7 .710 18,0 177 @ 100MHz

CF28B1500 1.725 43,8 1.232 31,3 1.720 43,7 .960 24,4 133 @ 100MHz

CF28B2000 2.350 59,7 1.851 47,0 2.309 58,6 .960 24,4 380 @ 100MHz

PART No. A B C D E F

IMPEDANCE IN OHMS

CW28B1642 .916 23,3 .885 22,5 .840 21,3 .282 7,2 1.250 31,8 .375 9,5 100 @ 100MHz

CW28B1805 1.105 28,1 .667 16,9 1.025 26,4 .340 8,6 1.250 31,8 .375 9,5 73 @ 100MHz

CW28B1937 1.236 31,4 .780 19,8 1.188 30,2 .425 10,8 1.250 31,8 .375 9,5 117 @ 100MHz

CW28B1984 1.282 32,6 .705 17,9 1.220 31,0 .525 13,3 1.250 31,8 .375 9,5 62 @ 100MHz

CW28B1501 1.789 45,5 1.232 31,3 1.720 43,7 .710 18,0 1.250 31,8 .375 9,5 177 @ 100MHz

CW28B1500 1.789 45,5 1.232 31,3 1.720 43,7 .960 24,4 1.250 31,8 .375 9,5 133 @ 100MHz

CW28B2000 2.414 61,3 1.851 47,0 2.309 58,6 .960 24,4 1.250 31,8 .375 9,5 380 @ 100MHz

Patent No. 5,003,278

PART No. A B C D E F (ref.)

IMPEDANCE IN OHMS

CV28B1642 .852 21,6 .885 22,5 .840 21,3 .282 7,2 .120 3,0 1.020 25,9 100 @ 100MHz

CV28B1805 1.040 26,4 .667 16,9 1.025 26,4 .340 8,6 .120 3,0 .820 20,8 73 @ 100MHz

CV28B1937 1.182 30,0 .780 19,8 1.188 30,2 .375 9,5 .120 3,0 .950 24,1 117 @ 100MHz

CV28B1984 1.218 30,9 .705 17,9 1.220 31,0 .500 12,7 .120 3,0 .940 23,9 62 @ 100MHz

PART No. A B C D E F

IMPEDANCE IN OHMS

CA28B1642 .882 22,4 .885 22,5 .840 21,3 .282 7,2 .375 9,5 .375 9,5 100 @ 100MHz

CA28B1805 1.070 27,2 .667 16,9 1.025 26,4 .340 8,6 .375 9,5 .375 9,5 73 @ 100MHz

CA28B1937 1.212 30,8 .780 19,8 1.188 30,2 .425 10,8 .375 9,5 .375 9,5 117 @ 100MHz

CA28B1984 1.248 31,7 .705 17,9 1.220 31,0 .525 13,3 .375 9,5 .375 9,5 62 @ 100MHz

CA28B1501 1.755 44,6 1.232 31,3 1.720 43,7 .710 18,0 .875 22,2 .875 22,2 177 @ 100MHz

CA28B1500 1.755 44,6 1.232 31,3 1.720 43,7 .960 24,4 .875 22,2 .875 22,2 133 @ 100MHz

CA28B2000 2.380 60,5 1.851 47,0 2.309 58,6 .960 24,4 1.000 25,4 1.500 38,1 380 @ 100MHz

cable snap

10

For attenuation properties by frequency, see page 32

28 material wideband ferrites- up to 1GHz applications

WITH SCREW MOUNT BASE. Ferrite assembly in fully enclosed nylon

case; various sizes are functional with wires and cables up to a .520”

(13,2mm) diameter. Mounting base is pre-installed at the intended location

with a screw through the .125” (3,2mm) diameter hole in the bottom. After

closing around wire and clasping shut, assembly snap-ts into base.

AF

E

D

CB

G

cable snap

CW28B0642 .995 25,2 .708 18,0 .780 19,8 .300 7,6 .177 4,5 .818 20,8 1.000 25,4 100 @ 100MHz

CW28B0805 1.180 30,0 .476 12,1 .965 24,5 .345 8,8 .177 4,5 1.003 25,5 .890 22,6 73 @ 100MHz

CW28B0937 1.293 32,8 .691 17,6 1.078 27,4 .425 10,8 .177 4,5 1.116 28,3 .930 23,6 117 @ 100MHz

CW28B0984 1.360 34,5 .547 13,9 1.145 29,1 .525 13,3 .177 4,5 1.183 30,0 .867 22,0 62 @ 100MHz

PART No. A B C D E F G

IMPEDANCE IN OHMS

WITH ADHESIVE MOUNTING BASE. Ferrite assembly in fully enclosed

nylon case; various sizes are functional with wires and cables up to a

.520” (13,2mm) diameter. After closing around wire and clasping shut,

assembly is snap-tted into its mounting base. May be installed in its

intended location before or after product assembly simply by removing

protective paper strip from base and pressing into place.

AF

E

D

CB

G

Adhesive Pad

cable snap

CA28B0642 .995 25,2 .708 18,0 .780 19,8 .300 7,6 .177 4,5 .818 20,8 1.000 25,4 100 @ 100MHz

CA28B0805 1.180 30,0 .476 12,1 .965 24,5 .345 8,8 .177 4,5 1.003 25,5 .890 22,6 73 @ 100MHz

CA28B0937 1.293 32,8 .691 17,6 1.078 27,4 .425 10,8 .177 4,5 1.116 28,3 .930 23,6 117 @ 100MHz

CA28B0984 1.360 34,5 .547 13,9 1.145 29,1 .525 13,3 .177 4,5 1.183 30,0 .867 22,0 62 @ 100MHz

PART No. A B C D E F G

IMPEDANCE IN OHMS

WITH PRESS FIT MOUNT. Ferrite assembly in fully enclosed nylon case;

various sizes are functional with wires and cables up to a .520” (13,2mm)

diameter. After closing around wire and clasping shut, assembly snap-ts

into mounting base. Base may be installed either before or after product

assembly by pressing the integral spring tab fastener into a .187” (4,7mm)

diameter hole.

A

F

E

D

C

H

B

G

cable snap

CF28B0642 .995 25,2 .708 18,0 .780 19,8 .300 7,6 .280 7,1 .183 4,6 1.000 25,4 .240 6,1 100 @ 100MHz

CF28B0805 1.180 30,0 .476 12,1 .965 24,5 .345 8,8 .280 7,1 .183 4,6 .890 22,6 .240 6,1 73 @ 100MHz

CF28B0937 1.293 32,8 .691 17,6 1.078 27,4 .425 10,8 .280 7,1 .183 4,6 .930 23,6 .240 6,1 117 @ 100MHz

CF28B0984 1.360 34,5 .547 13,9 1.145 29,1 .525 13,3 .280 7,1 .183 4,6 .867 22,0 .240 6,1 62 @ 100MHz

PART No. A B C D E F G H IMPEDANCE IN OHMS

Ferrite assembly bonded to nylon strap; functional with wires and cables up to

a 1.00” (25,4 mm) diameter. Holes are provided for screw mounting.

AD

F

CB

E

PART No. A B C D E F

IMPEDANCE IN OHMS

TC28B0550 .685 17,4 1.105 28,1 .685 17,4 .214 5,4 1.102 28,0 .195 5,0 281 @ 100MHz

TC28B0617 .740 18,8 1.125 28,6 .740 18,8 .276 7,0 1.215 30,9 .195 5,0 273 @ 100MHz

TC28B0642 .785 19,9 .630 16,0 .785 19,9 .320 8,1 1.335 33,9 195 5,0 100 @ 100MHz

TC28B0805 .948 24,1 .500 12,7 .948 24,1 .404 10,3 1.498 38,0 .195 5,0 73 @ 100MHz

TC28B0937 1.127 28,6 .551 14,0 1.127 28,6 .449 11,4 1.677 42,6 .195 5,0 117 @ 100MHz

TC28B1123 1.320 33,5 1.125 28,6 1.320 33,5 .543 13,8 2.000 50,8 .195 5,0 220 @ 100MHz

TC28B0984 1.127 28,6 .500 12,7 1.127 28,6 .591 15,0 1.677 42,6 .195 5,0 62 @ 100MHz

TC28B1251 1.375 34,9 .875 22,2 1.375 34,9 .750 19,1 1.884 47,9 .195 5,0 138 @ 100MHz

TC28B1501 1.628 41,4 1.000 25,4 1.628 41,4 .750 19,1 2.150 55,5 .195 5,0 177 @ 100MHz

TC28B1500 1.628 41,4 1.000 25,4 1.628 41,4 1.000 25,4 2.150 55,5 .195 5,0 133 @ 100MHz

TC28B2000 2.125 54,0 1.500 38,1 2.125 54,0 1.000 25,4 2.860 72,6 .281 7,1 380 @ 100MHz

cable clamp

Ferrite assembly in fully enclosed nylon case; functional with wires and

cables up to a .520” (13,2mm) diameter. Snap closed around wire by

clasping shut to position assembly. Cable tie-wraps may be threaded

through the loops on each side.

Larger I.D.’s permit multiple cable turns for greater impedance effect. See

page 6, gures 3 and 4.

A F

E

D

CB

G

cable snap

CS28B0642 .923 23,4 .708 18,0 .780 19,8 .300 7,6 .143 3,6 .818 20,8 1.000 25,4 100 @ 100MHz

CS28B0805 1.095 27,8 .476 12,1 .965 24,5 .345 8,8 .100 2,5 1.003 25,5 .890 22,6 73 @ 100MHz

CS28B0937 1.222 31,0 .691 17,6 1.078 27,4 .425 10,8 .098 2,5 1.116 28,3 .930 23,6 117 @ 100MHz

CS28B0984 1.275 32,3 .547 13,9 1.145 29,1 .525 13,3 .095 2,4 1.183 30,0 .867 22,0 62 @ 100MHz