Telecom Circuit Protection Selection Guide

SELECTION GUIDE
Telecom
Circuit Protection
Circuit Protection Solutions
The Bourns Mission
Our goal is to satisfy customers on a global basis
while achieving sound growth with technological
products of innovative design, superior quality
and exceptional value. We commit ourselves to
excellence, to the continuous improvement
of our people, technologies, systems, products
and services, to industry leadership and to
the highest level of integrity.
Index
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2
Applications - What Protection do you Need?
What is a Surge? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3
What is Protection? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3
Lightning - Global and Different . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4
Where will the System be Used? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5
Coordination is No Longer Optional . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
System Technology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
Location . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
Application - Central Office (CO) and Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9
Application - Customer Premise Equipment (CPE) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
Digital Technology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
Useful Sources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
Network Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16 & 17
Technology - Which Protection Technology is Right for the Equipment?
The Basics - Overvoltage and Overcurrent . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18
What Happens After a Surge or if the Device Fails? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18
Speed and Accuracy are Major Factors in Determining Equipment Stress Levels . . . . . . . . . . . . . . . . . . . .19
Technology Selection - Overvoltage Protectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21
Gas Discharge Tubes (GDTs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22
Thyristor-Based Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
Metal Oxide Varistors (MOVs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
Transient Voltage Suppressors (TVSs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25
Technology Selection - Overcurrent Protectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25
Positive Temperature Coefficient (PTC) Thermistors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .26
Fuses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27
Heat Coils . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27
Line Feed Resistors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27
Thermal Switches . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .28
Modes of Overvoltage Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .28
Technology Selection - Integrated Solutions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .29
Multi-Stage Protectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .29
Integrated Line Protection Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .30
Product Selection Guides
Gas Discharge Tubes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
Multifuse® PPTC Resettable Fuses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .34
TISP® Thyristor Surge Protectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .35
Surge Line Protection Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .41
Telefuse™ Telecom Fuses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .43
1
Introduction
Bourns is pleased to present this comprehensive
guide to Telecom Circuit Protection, encompassing
our broad range of technologies and products. This
guide will provide the background information and
selection recommendations needed to ensure that
your next project achieves the level of cost-effective
field reliability demanded by today’s customers.
Technical and Design Support – Bourns’ team of
specialized Sales and Field Application Engineers are
ready to bring additional in-depth expertise to your
next project. Through our interactive website and
customer service locations, Bourns is always available
to answer circuit protection design questions and
provide valuable assistance and support.
Bourns commissioned a survey of Telecom Circuit
Protection users worldwide to determine their priorities and needs. We found that reliability, technical
and design support, and exemplary knowledge of
protection technology were by far the three most
cited items. Bourns is committed to meeting each of
these three requirements:
Knowledge of Protection Technology – Bourns
Reliability – Reliability requires an understanding of
the capabilities and specifications of circuit protection
technology. Bourns has a global reputation for quality
products, and our circuit protection devices have
consistently demonstrated reliability in field applications. Bourns is committed to the complete support
of a circuit protection solution for the life of a
program.
2
boasts the industry’s widest range of Telecom overvoltage and overcurrent protectors. Our active
involvement in international protection standards
organizations ensures world-class technology and
applications expertise.
Bourns continues to develop an innovative range of
integrated circuit protection products using our
knowledge and expertise to combine multiple
technologies into optimized single devices designed
to save both cost and board space. Whether you need
a single product or a complete protection solution,
Bourns Telecom Circuit Protection team is there to
help you. We look forward to working with you.
Applications - What Protection is Needed?
Communication systems are vulnerable to electrical
damage from lightning or other surges. As systems
become more complex, they also become more
vulnerable. Balancing the cost, standards compliance
and field reliability of protection is both a commercial
and technical challenge, compounded by the additional performance constraints of modern digital
networks such as xDSL.
This section is intended to outline those challenges,
illustrate the fundamentals of protection and identify
those international standards relevant to specific
applications. The next section will examine individual
protection technologies and their selection.
Bourns engineers have helped designers with major
projects in every region of the world, successfully
protecting hundreds of millions of telephone circuits.
Our uniquely broad range of protection solutions
enables us to identify the most suitable technology
for each application. Whether the goal is to achieve
standards compliance or tackle a specific field problem, Bourns’ experience and product offering are the
solution to a myriad of design requirements.
Reliability Tip
Complying with standards does not guarantee
field reliability.
What is a Surge?
A “surge” is a short-term increase in voltage or
current. Both lightning and the AC power distribution
system cause surges, but of very different magnitudes
and durations (see Table 1). These events can either
be via direct contact or by field or resistive coupling
from events close to the telephone system, resulting
in a wide variety of threats. For example, the effects
of a power line fault caused by lightning may even be
more threatening to the telephone system than the
original lightning.
The dangers of large voltages and currents are obvious,
but time is also important. Lightning is too fast for
bulk heating to be critical, whereas for the longer
term currents of AC power faults, heating effects
are significant for device survival and safety. Direct
contact to the AC (power cross) causes high currents,
while lower currents result from power induction.
Obviously, a single device protection solution is
seldom possible.
Amplitude
Lightning
Duration
Bulk
Heating
kA, kV
µs
Negligible
Power Cross
60 A
<30 mins
Significant
Power
Induction
7A
<30 mins
Crucial
Table 1. Different surge sources result in very different
effects
Reliability Tip
Effective protection usually requires overcurrent and
overvoltage devices.
What is Protection?
Protection performs several key functions as outlined
in Figure 1: first it must prevent or minimize damage
caused by a surge; then it must ensure that the system
returns to a working condition with minimal disruption to service. It is vital that under normal conditions
the protection does not interfere with the signal,
creating special challenges for xDSL and other digital
technologies. The protection must also fail in a safe
manner during overstress.
Field reliability
Quality
of service
Standards
compliance
Signal
integrity
Figure 1. Protecting “Quality of Service” requires
more than standards compliance
3
Within each of the core protection types listed in
Table 2, there are several individual technologies.
These will be reviewed in more detail in the
Technology section. Each technology has different
strengths and weaknesses, and only by understanding
their relative merits can protection be optimized for
a given installation. A quick review of Table 3
demonstrates that no single ideal solution exists for
all locations within the telephone network so cascaded
protection is often employed.
Protection
Type
Action
Connection
Overcurrent
Limit peak current
Series (or parallel
for primary)
Overvoltage
Limit peak voltage
Parallel
Overcurrent
and
Overvoltage
Coordinate voltage
and current
protection
Combination
boundary of the premises. It is designed to redirect
the bulk of the surge energy away from personnel
and equipment by passing significant current to
ground. Secondary protection (Figure 3) is optimized
to protect the most sensitive parts of the equipment
from any residual voltage surges let through by the
Primary protector. Some telecommunications ICs
have very precisely defined time-dependent Safe
Operating Areas, requiring precise and predictable
behavior as illustrated in Figure 4. There is typically
some resistance added between the Primary and
Secondary protection, either as part of the system
requirements or the protection regime.
Primary Protection
Table 2. Protection falls into three basic types
Overvoltage
Speed
Accuracy
Current
Rating
GDT
Fair
Poor
Very high
Thyristor
Fair
Good
High
Protected
side
Unprotected
side
Overcurrent
protector
Overvoltage
protector
Figure 2. Typical format for Primary protection
MOV
Fast
Poor
High
TVS
Very fast
Good
Very low
Secondary Protection
Overcurrent
protector
Accuracy
Current
Rating
Polymer PTC
Thermistor
Slow
Good
Low
Ceramic PTC
Thermistor
Slow
Good
Low
Fuse
Very slow
Fair
Medium/
High
Heat Coil
Very slow
Poor
Low
Thermal Switch
Very slow
Poor
High
Table 3. Summary of technology characteristics
Primary protection (Figure 2) diverts most of the
surge energy away from the more sensitive/important
areas of the system and is typically located at the
4
Protected
side
Speed
Unprotected
side
Overcurrent
Overvoltage
protector
Figure 3. Typical format for Secondary protection
Lightning - Global and Different
Weather does not understand national boundaries,
and varies with geography as shown in Figure 5.
Partly for this reason, local standards have evolved to
describe a lightning strike, usually containing major
similarities, and critical differences. However, meeting
each local standard is only the start of protection
PBL 3762A SLIC Ring and Tip Voltage Withstand vs Time
1 µs
10 ms
0
Time
Where will the System
be Used?
VBAT
-50
VBAT -20 V
10 ms
Surge levels depend on
both the original source
energy and how it is disDC and 10 ms pulse rating increased
to -70 V (independent of VBAT value)
tributed. Line density
by use of series battery feed diode
varies considerably in
Central Office or Access
Equipment within urban
and rural areas. At higher
densities, individual line surges tend to be smaller as
energy is spread over multiple pair counts. In loop
applications pair counts tend to be lower, and in fiber
rich environments, these loops are becoming shorter
in length. Both trends tend to increase the surge energy
distributed over individual lines.
-70
1 µs
VBAT -40 V
-90
-100
-110
0.25 µs
-120
VBAT -70 V
Figure 4. Telecom ICs have precisely defined
Safe Operating Areas, requiring precise protection
For example, high exposure lines (remote terminals
and less than 1,000 ft/300 m line length) with severe
lightning surges are required under GR-974 and
GR-1361 to have protection requirements of a current
carrying capability of 2000 A 10/250. Within areas of
similar flash density, factors such as ground resistivity
(ρ), as well as the type of environment and equipment
can have a direct impact on the resultant surge
Figure 5. Lightning is global, but not uniform, as data
from space emphasizes
Rural
Stress
Suburban
Stress
Hig
Ground Potential Rise
hF
lash
Den
sity
Further Information
See thunder.nsstc.nasa.gov
for the latest published
lightning plot.
lash D
Low F
ensit
Ground Resistance
y
Urban
Stress
Number of Lines
Central Office
-80
Access
-60
Customer Premise
5
0.25 µs
Equipment Stress Level
10
Line Stress Level
Voltages (with VBAT set to –50 V) – V
15
design. It requires a
deeper understanding of
protection to achieve the
competitive advantage of
reliable operation under
field conditions.
Number of Lines
Figure 6. Location influences stress levels within telecommunications equipment
5
Uncoordinated
Coordinated
P2
Reliability Tip
Low flash density and high soil resistivity can produce
more stress than high flash density and low resistivity.
coordinated. From the year 2000 forward, coordination of protection has been mandatory as part of
ITU-T K.20, K.21, and K.45. Designing a coordinated
protection scheme is no longer just good practice; it
is a prerequisite to international compliance.
Practical guidelines for protection coordination are
presented in the Technology section.
Limiting
Voltage
at
Sparkover
Instant
V
R+
amplitude, as illustrated in Figure 6. Therefore,
depending on where it is deployed, each protection
scheme will have different field reliability. For global
deployment, once standards are met, engineers
should understand potential field stress levels in
order to predict levels of field reliability. For example,
ITU-T K.44 Figure I.1-8/K.44 shows field AC induction surge levels measuring between 2 A, 3 s and 8 A,
0.2 s, implying that the sensitivity and dissipation of
current protection can have a significant impact on
maintenance issues.
P1
Safety Tip
Equipment deployed in customer premises, and
accessible to untrained personnel, has additional
safety requirements.
Coordination is No Longer Optional
6
Equipment Electronics
Unprotected Side
Consider the generic protection scheme of Figure 7.
P1 is the primary protection, R is a coordination and
current limit resistor and P2 is the secondary protection. Coordination will not occur if the secondary
protection limiting voltage of R and P2 is lower than
the sparkover voltage of P1 at the expected sparkover
instant (see Figure 8). Both P1 and P2 may be
acceptable for individual
purposes, but comCoordination
bined the interaction
of Protection
defeats the overall
Coordination Resistance
protection strategy.
R
The potential for
interaction is present
P Coordination P
1
2
wherever more than
one protector is on the
same line. The action
Primary
Secondary
Protection
Protection
of each device, whether
within a single equipFigure 7. Coordination of
ment or between
protection is now mandatory
equipments must be
for ITU-T compliance
• low current
• slow rise time
• long duration
Impulse
• high current
• fast rise time
• short duration
Figure 8. With different time-current characteristics,
primary/secondary coordination is crucial
Standards Tip
Coordination of primary and secondary protection is
now mandatory for ITU-T equipment compliance.
Standards
There are numerous regional and national standards,
and even focusing on ITU-T and USA standards can
be confusing. The Location section highlights where
key standards are applicable within specific applications. As the standards change frequently, Bourns
recommends obtaining the latest versions of the
relevant documents. For example, the ITU-T recently
introduced the concept of two-level “Basic” and
“Enhanced” requirements within a single standard.
For the future, work is underway at the World Trade
Standards Tip
In addition to international standards, it is
always important to check the local requirements
for target markets.
Further Information
Many standards include valuable application guidance.
This means that a system needing maintenance
before returning to service, perhaps by replacing a
fuse, could still be compliant. Upgraded protection,
or careful coordination of protectors and current
limiting devices could permit passing a Type A surge
with an automatic return to service. This scenario
may yield a higher component, but a lower lifetime
cost.
Equipment
Organization to consider unifying these multiple
requirements into a single standard.
Since real world surges are unpredictable, even when
standards are mandatory, compliance does not
guarantee reliability. Satellite observation has
enabled global counting of lightning flashes and
work is underway to investigate the multiple strikes
typically present in each flash. Since real world
multiple surges are currently not modeled in the
standards, they represent another area where field
reliability is not assured. It is likely that standards will
be extended to include such multiple surge tests.
Application
Standards
Requirements
Compare
Solutions
Reliability Tip
Complying with standards does not guarantee
field reliability.
Figure 9. Compliance, technical and commercial
requirements must influence protection design
Harsh operating conditions, high access or repair
costs and demands for superior quality of service
may all justify additional protection beyond the
minimum levels within the standards. To illustrate
the interaction of standards and protection design
shown in Figure 9,
Bandwidth
TIA/EIA-IS-968 (FCC
(bps)
Part 68) specifies two
levels of surge, Type A
POTS
56 k
and Type B. TelecomPair Gain
160 k
munications equipment
ISDN
128/144 k
must survive and be
T1 / E1
1.5 - 2 M
operational after Type
xDSL
2-50 M
B surges, but is allowed
HDSL
1.5M
to be non-operational
after Type A surges.
Table 4.
System
Voltage
(Maximum)
Impedance
(Ω)
Capacitance
of Shunt
Element
Protection
Resistance
270 V
600
Non-critical
Non-critical
145 V DC
150
Low
Low
120 V DC
150
Low
Low
150 V DC
120
Very low
Low
Various
<100
Very low
Very low
190 V DC
<100
Very low
Very low
System technology places different limitations on protection
7
on protection, both to permit increased bandwidth
and to provide more precise protection of increasingly sophisticated and vulnerable line-card
components. Recently, Telcordia issued a revision of
GR-974 that addresses Next Generation Broadband
Protectors. Bourns engineers worked with Telcordia
on the development of this technology neutral
specification.
Standards Tip
Some standards offer multiple levels of compliance.
Designers must identify the right level for their
target market.
Reliability Tip
Protection must be matched to the value and
vulnerability of the equipment, as well as the
down time and repair cost.
Location
Protection requirements vary depending upon where
the equipment is deployed (see Figure 10 and Tables
5 and 6). The Central Office (CO) or exchange and
Customer Premises Equipment (CPE) are easily
identified. Access is essentially everything else and
typically covers intermediate network facilities such
as those used to consolidate POTS lines onto fiber or
coax. Although ITU-T applies different standards to
each, from a protection point of view, CO and Access
System Technology
The level of protection required and its justification
depends on what is being protected. Table 4 and the
following sections emphasize each system technology
and the particular requirements and constraints
placed on protection design.
The dynamics of a
world market have a
significant impact on
protection design. For
example, as Central
Office copper lines
transfer to access
equipment, protection
must be increasingly
self-resetting and more
effective at reducing
expensive repair callouts. Although line
density is increasing
in urban areas and
reducing stress levels,
installations are reaching more remote areas
where surge threats
increase substantially
due to a lack of
“shielding” from taller
structures.
Digital services are also
making new demands
8
MDF
MDF Line cards
Network
Interface
Device
(NID)
NID
Equipment Rack
ITE
Customer Premise
(Subscriber)
ITE
Access
Central Office
(Telecom Center)
Outside
Plant
Customer Premise
(Subscriber)
Access = Any equipment between the subscriber and the Telecom Center
Figure 10. Location determines which standards are applicable
International
Primary
Customer
K.28
Customer
NID
Access
CO
MDF
X
X
X
K.20
Secondary
X
K.21
X
K.44
X
K.45
Safety
CO
X
X
X
IEC 60950
X
Notes:
K.44 describes the circuits to be used for testing.
K.36 provides useful guidelines for the selection of protective devices.
Table 5. Specific International standards for location within the system
are very similar. CPE standards, however, reflect the
different technical and safety issues of an end user
site.
Standards Tip
Be sure to identify the right standards for your type
of equipment, and for your planned regions of
deployment.
USA
Customer
Customer
NID
GR-974
Primary
X
GR-1361
X
RUS PE-80
X
TIA/EIA-IS-968
(FCC Part 68)
Secondary
Safety
X
GR-1089
X
UL 60950
X
Table 6. Specific USA standards for location within the
system
Application - Central Office (CO) and Access
In addition to device technology, demand for
increased density on line cards also requires attention
to packaging. Surface mount packages and those
containing multiple devices, including multi-chip
modules with multiple technologies improve line
density.
Connected directly to the telephone line, integrated
circuits such as SLICs and LCASs are perhaps the
most vulnerable on the
CO
network. These are
Access
CO
MDF
specialized components
requiring precise proX
X
tection normally
X
X
provided by thyristorX
X
based protectors.
Working with several
X
X
major suppliers of
these circuits, Bourns
developed a broad
range of protectors
designed to maximize
protection for specific
models of line card
ICs, as illustrated in
Figure 11.
PBL 3xxx SLIC Voltage Withstand and
TISPPBLx Voltage Limiting vs Time
40
Voltage – V
30
20
PBL 3762A
PBL 3796
10
TISPPBLx
PBL 386 20/1
0
VBATM
VBATM -10
VBATM -20
VBATM -30
VBATM -40
VBATM -50
VBATM -60
VBATM -70
Time
10 µs
1 µs
0.25 µs
1 ms
10 ms
TISPPBLx
PBL 386 20/1
PBL 3796
PBL 3762A
Recent changes to
ITU-T equipment
standards made
protection coordination
mandatory. Documentation increased by over
one hundred pages,
emphasizing the need
for timely review of
new requirements. As
well as monitoring
changes, Bourns is an
active contributor to the
standards process.
Figure 11. Thyristor protectors provide the precision to protect SLICs
9
Data Sheet Tip
Check for space-saving multiple device, or
multiple technology components as well as
surface mount packaging.
Standards Tip
Standards are updated, often with significant impact.
Monitor current and future changes to confirm that
your design remains compliant.
CO and Access - Key Relevant Standards
International
USA
Primary
protection
ITU-T K.28 (Thyristor)
ITU-T K.12 (GDT)
IEC 61643-311 (GDT)
GR-974
(Solid State &
Hybrid)
GR-1361 (GDT)
RUS PE-80 (GDT)
Secondary
protection
ITU-T K.20 (CO)
ITU-T K.45 (Access)
ITU-T K.44
IEC 61643-21
GR-1089
Component
standards
ITU-T K.12 (GDT)
IEC 61643-311 (GDT)
IEC 61643-321 (TVS)
IEC 61643-341
(Thyristor)
IEEE Std C62.31
(GDT)
IEEE Std C62.32
(Carbon Block)
IEEE Std C62.33
(MOV)
IEEE Std C62.35
(TVS)
IEEE Std C62.37
(Thyristor)
ESD
protection
IEC 61000-4-2
IEC 61000-4-2
CO and Access - Recent / Future Standards
Organization
ITU-T
Standard
Comment
K.12, K.20, K.44
& K.45
New/revised
in 2000
K.44
Revision
anticipated
TELCORDIA
GR-974, GR-1089
Revised for
2002
EN/IEC
61643-311-321,
341, -21
New for 2001
EN/IEC
MOV, Modules
Anticipated
2002-2004
IEEE
C62.31 (GDT), C62.32
(Carbon Block),
C62.37 (Thyristor)
In revision for
2003
Reaffirmed in
2002
ACTA
TIA/EIA-IS-968
New for 2001,
Replaces FCC
Part 68
CO and Access - Suitable Protection Technologies
Primary
Secondary
GDT
Y
H
Thyristor
Y
Y
MOV
H
TVS
H
PTC Thermistor
Y
Fuse
Y
Y
Thermal Switch
Y
Heat Coil
A
Line Protection
Module
Voltage
Protection
Current
Protection
Y
Y = Suitable
H = Suitable as part of GDT hybrid
A = Suitable except for ADSL and higher data rates
10
CO and Access - Relevant Sub-assemblies
Surge
SLIC
PROTECTOR
SLIC 1
VBAT1
C1
100 nF
0V
TISP6NTP2A
SLIC 2
4A12P-516-500
VBAT2
IG
C2
100 nF
0V
Integrated Line Protection for Multiple SLICs
Surge
RING/TEST
PROTECTION
TEST
RELAY
RING
RELAY
SLIC
RELAY
SLIC
PROTECTOR
SLIC
TIP
Th1
S3a
Th4
S2a
S1a
Th3
Th5
Th2
RING
2026-xx
or
2036-xx
4B06B-524-400
or
4B06B-522-500
TISP
3xxxF3
or
7xxxF3
S3b
S1b
S2b
TISP
61089B
VBATH
TEST
EQUIPMENT
C1
220 nF
RING
GENERATOR
Linecard Protection with Electromechanical Relays
11
CO and Access - Relevant Sub-assemblies (continued)
RING
RELAY
Surge
SLIC
RELAY
SLIC
TIP
Th1
Th3
SW1
SW3
LCAS
Th2
Th4
RING
4B06B-540-125/219
SW4
R2
SW2
CONTROL
LOGIC
2026-xx
or
2036-xx
Vbat
R1
VRING
VBAT
SW5a
SW5b
RING
GENERATOR
Linecard Protection with Solid-State Line Card Access Switch
Application - Customer Premise Equipment (CPE)
Unlike Central Office or Access applications, CPE
connections are typically only 2-wire, removing the
need to balance R and C on each line. Two key
demands for CPE equipment relate to regenerated
POTS lines and easy maintenance. As with CO
applications, space-saving packaging is important for
POTS SLIC protection. Thyristor-based devices offer
the accuracy required with protectors matched to
specific ICs or families simplifying the selection task.
CPE - Key Relevant Standards
International
USA
Primary
protection
ITU-T K.28
(Semiconductors)
ITU-T K.12 (GDT)
IEC 61643-311 (GDT)
GR-974
(Solid State &
Hybrid)
GR-1361 (GDT)
RUS PE-80 (GDT)
IEEE C62.31 (GDT)
IEEE C62.32
(Carbon Block)
Secondary
protection
ITU-T K.21
ITU-T K.22 (ISDN-S)
ITU-T K.44
IEC 61000-4-5
(Intra-Building)
IEC 61643-21
TIA/EIA-IS-968
(FCC Part 68)
GR-1089-CORE
(Intra-building)
IEC 60950
UL 1950 / 60950
IEC 61000-4-2
IEC 61000-4-2
Safety
ESD
protection
12
CPE - Recent / Future Standards
As with CO and Access, the ITU-T standards have
recently expanded significantly.
Organization
ITU-T
TELCORDIA
Standard
CPE - Suitable Protection Technologies
Comment
Secondary
GDT
Y
H, L
Thyristor
U
Y
MOV
H
Y
K.12, K.44 & K.21
New/Revised
in 2000
TVS
H
Y
K.44
Revision
anticipated
PTC Thermistor
Y
Y
Fuse
GR-974, GR-1089
Revised for
2002
EN/IEC
61643-311, -321,
-341, -21
New for 2001
EN/IEC
MOV, Modules
Anticipated
2002-2004
FCC
TIA/EIA-IS-968
(FCC Part 68)
In revision for
2002
IEEE
C62.31, C62.32
In revision for
2003
C62.37
Reaffirmed in
2002
TIA/EIA-IS-968
New for 2001,
Replaces FCC
Part 68
ACTA
Primary
Y
Thermal Switch
Y
Heat Coil
A
Y=
A=
H=
L=
U=
Voltage
Protection
Current
Protection
Suitable
Suitable except for ADSL and higher data rates
Suitable as part of hybrid
Suitable for LAN or ADSL use
Suitable for urban high density deployment only
CPE - Relevant Sub-assemblies
MF-SM013/250-2
‡
+t˚
B1250T †
Telefuse™
†
‡
TIA/EIA-IS-968 / UL 60950
ITU-T K.21 (Basic)
Tx
TIP
C
TISP4360MM
or
TISP4360H3
Sig nal
2027-xx
or
2035/37-xx
RING
Basic ADSL Interface
13
CPE - Relevant Sub-assemblies (continued)
MF-SM013/250-2
Sol id
Sta te
Relay Isolation B arrier
‡
+t˚
B1250T †
Telefuse™
Pol arity
Bridge
RING
†
‡
TIA/EIA-IS-968 / UL 60950
ITU-T K.21 (Basic)
Ho ok
Switch
Pow er
D1 D2
OC1
D3 D4
Rx Signal
OC2
TIP
Ring
Detector
TISP4350H3 †
or
TISP4290L3 ‡
Tx Sig nal
Basic Electronic Hook Switch Protection
MF-SM013/250-2
‡
+t˚
B1250T †
™
Telefuse
Ring
Detector
Pol arity
Bridge
RING
Relay
C1
R1
TISP4350H3 †
2027-xx
or
2035/37-xx
TISP4290L3 ‡
C2
D1 D2
D3 D4
D5
D6
Hook
Switc h
C3
DC
Sin k
T1
Sig nal
R2
TIP
D7
TIA/EIA-IS-968 / UL 60950
‡ ITU-T K.21 (Basic)
†
OC1
Isolation B arrier
Basic Electromechanical Hook Switch Protection
Digital Technology
As bandwidth increases to meet escalating data
transmission needs, absolute values of balance and
insertion loss become important design considerations
shown by Figure 12. In addition, balancing C and R
for tip and ring, both at installation and over the
longer term are important to minimizing EMC
problems. This puts a premium on accuracy and
stability, as well as relative value. However, series
resistance attenuates the signal, reducing the practical
transmission distance of xDSL, thereby making
14
resistance a performance consideration for xDSL. For
this reason, fuses are often preferred over PTC thermistors for their lower resistance current protection
despite the maintenance issue of being non-resetting.
This underlines that hard rules are not feasible in
protection since resetting devices would otherwise be
ideal for CO and Access applications.
Similarly, since the capacitance of all semiconductors
is voltage-dependent and this change of capacitance
may create harmonic distortion for digital signals
and unbalance the line; careful selection is important.
For the highest data rates, CAT5/100 MHz and
above, GDTs are attractive.
2002 Technology Capacitance Comparison
Useful Sources
IEC
International Electrotechnical
Committee
www.iec.ch
IEEE
Institute of Electrical and Electronic
Engineers
www.ieee.com
ETSI
European Telecommunications
Standards Institute
www.etsi.org
FCC
Federal Communication
Commission
www.fcc.gov
ITU
International Telecommunications
Union
www.itu.int
JEDEC
Joint Electron Device Engineering
Council
www.jedec.org
UL
Underwriters Laboratories
www.ul.com
TELCORDIA
Telcordia Technologies
(Formerly Bellcore) USA
www.telcordia.com
TIA
Telecommunications Industry
Association
www.tiaonline.org
ACTA
Administrative Council for Terminal
Attachments
www.part68.org
100
80
60
50
40
30
Suitable for ADSL
Hybrids
LV Thyristor
HV Thyristor
Thyristor "Y"
2
1.5
Thyristor+Diode
10
8
6
5
4
3
GDT+MOV
20
15
GDT
Capacitance to Ground - pF
200
150
1
Protector Type
Figure 12. The value, stability and balance of
capacitance and resistance are becoming vital for
digital technologies
Performance Tip
R, C and L values of protection can be critical for
digital lines. Balance and insertion loss are critical.
Datasheet Tip
Thyristor capacitance changes with applied voltage.
Ensure that capacitance is stated for defined voltages,
not just as a typical value.
15
Circuit Protection Solutions
16
17
Which Protection Technology is Right for
the Equipment?
Overcurrent limiting - interrupting
Source
Impedance
Surge
Overcurrent
Protection
Surge Current
Interrupting
Interrupting
DO NOT
ENTER
Protected Load
No single protection technology offers an ideal
solution for all requirements. Good protection
design necessitates an understanding of the performance trade-offs and benefits of each device type, as
well as the terminology used in their specifications.
Adequate grounding and bonding, to reduce potential
differences and provide a low impedance current
path, is a prerequisite for coordinated system
protection (GR-1089-CORE, Section 9).
Overcurrent
Overcurrent limiting - reducing
Surge
Overcurrent
Protection
Surge Current
Reducing
Reducing
REDUCED
CURRENT
AHEAD
Overcurrent
Overcurrent limiting - diverting
Source
Impedance
Surge
Surge Current
Diverting
Diverting
Overcurrent
Protection
O N LY
Protected Load
Protection devices fall into two key types, overvoltage
and overcurrent. Overvoltage devices (see Figure 1)
divert fast surge energy (such as lightning), while
most overcurrent devices (see Figures 2a-2c) increase
in resistance to limit the surge current flowing from
longer duration surge currents (50/60 Hz power
cross). There are two types of voltage limiting protectors: switching devices (GDT and Thyristor) that
crowbar the line and clamping devices (MOV and
TVS). The inset waveforms of Figure 1 emphasize
that switching devices results in lower stress levels
than clamping devices (shaded area) for protected
equipment during their operation. Functionally, all
voltage protectors reset after the surge, while current
protectors may or may not, based on their technology.
For example, PTC thermistors are resettable; fuses
are non-resettable as shown in Table 1.
Source
Impedance
Protected Load
The Basics – Overvoltage and Overcurrent
Overcurrent
Figure 2a-2c. Overcurrent protection isolates the
equipment by presenting a high
impedance
Overvoltage limiting - clamping and switching
Source
Impedance
Protected Load
Surge
Overvoltage
O N LY
Overvoltage
Protection
Surge Current
Clamping
Overvoltage
Protection
Threshold Voltage
Switching
Overvoltage
Protection
Source and load voltages
Figure 1. Overvoltage protection provides a shunt
path for surges
18
What Happens After a Surge or if the Device Fails?
In addition to preventing a surge from destroying
equipment, resettable devices return the equipment
to pre-event operation, eliminating maintenance cost
and maximizing communications service. In addition,
lightning typically consists of multiple strikes. It is,
therefore, essential to consider subsequent surges.
Because lightning and power cross standards are not
intended to represent the maximum surge amplitudes
in the field, an understanding of what happens under
extreme conditions is equally important.
Overvoltage
Overvoltage
Action
Connection
Examples
Voltage switching
Shunt
GDT, Thyristor
Voltage clamping
Shunt
MOV, TVS
Overcurrent
Action
Resettable
Connection
Series
Suitable
for
Primary
(P) or
Secondary
(S) 1, 2
Normal
Operation
After
Operation
Still
Protecting?
Line
Operating?
P or S
Reset to
Normal
Yes/No
No/Yes
GDT +
Thermal
Switch
P
Reset to
Normal
Yes
No
Thyristor
P or S
Reset to
Normal
Yes
No
Thyristor
+ Thermal
Switch
P
Reset to
Normal
Yes
No
MOV
S
Reset to
Normal
No
Yes
TVS
S
Reset to
Normal
Yes
No
GDT
Examples
PTC thermistor
- Ceramic
- Polymer
Non-resettable
Series
Fuse
Non-resettable
Shunt or
Series
Heat coil
Non-resettable
Series
LFR (Line Feed
Resistor)
Non-resettable
Across
voltage
limiter
Fail-short device
for thermal
overload
Overcurrent
Table 1. The basic classes of protection devices
Normal
Operation
A shunt device failing open circuit effectively offers
no follow-on protection, although under normal
conditions the telephone line will operate. If the
device fails to a short circuit, the line is out of service,
but further damage is prevented. In addition, other
issues such as exposed areas prone to heavy surge
events or remote installations where maintenance
access is difficult may strongly influence selection of
the most suitable protection technology (see Table 2).
After
Operation
Reliability Tip
Complying with standards does not guarantee
field reliability.
1
Speed and Accuracy are Major Factors in
Determining Equipment Stress Levels
The behavior of each technology during fast surge
events can have a substantial effect on maximum
stress as summarized in Table 3. In addition to device
tolerance, each device requires a finite time to operate,
during which the equipment is still subjected to the
rising surge waveform. Before operation, some
After Excess
Stress 3
2
3
After Excess
Stress 3
Still
Protecting?
Line
Operating?
PTC Thermistor
Reset to
Normal
Yes
No
Fuse
Line
Disconnected
Yes
No
Heat Coil
Line
Shorted
or
Open
Yes
No
Yes
No
Thermal Switch
Line
Shorted
Yes
No
LFR
Both
Lines
Disconnected
Yes
No
Primary protection applications typically require
specific fail-short protection.
Secondary protection requires a fused line (USA).
The failure mode depends on the extent of the excess stress.
Comments made for a typical condition that does not fuse
leads.
Table 2. The status after the protection has operated
can be a significant maintenance/quality of
service issue
19
Overvoltage Limiters
Clamping
Switching
Class
Type
Performance
Technology
Voltage
Limiting
Speed
Voltage
Precision
Impulse
Current
Capability
Low
Capacitance
BEST
Gas Discharge Tube
BEST
Thyristor
Metal-Oxide Varistor
TVS
BEST
Overvoltage protection
technologies may be
summarized as follows:
BEST
Table 3a. No overvoltage technology offers an ideal solution for all applications
Overcurrent Limiters
Diverting
Interrupting
Reducing
Class
Type
Performance
Technology
Fast
Operation
Resistance
Stability
Low
Operating
Current
Polymer PTC Thermistor
BEST
BEST
Ceramic PTC Thermistor
BEST
BEST
Fuse
BEST
Line Feed Resistor
BEST
Heat Coil
Low
Series
Resistance
BEST
• GDTs offer the best
AC power and high
surge current capability. For high data rate
systems (>30 Mbs),
the low capacitance
makes GDTs the
preferred choice.
• Thyristors provide
better impulse protection, but at a lower
current.
• MOVs are low cost
components.
BEST
Thermal Switch
technologies allow significant overshoot
above the ‘operating’
level. The worst-case
effects determine the
stress seen by the equipment and not just the
nominal “protection”
voltage or current (see
Figure 3).
BEST
BEST
Table 3b. No overcurrent technology offers an ideal solution for all applications
• TVS offers better
performance in
low dissipation
applications.
Voltage impulse
Device operating delay - Voltage effect
depends on impulse rate of rise
Voltage
Maximum Overshoot
Maximum AC
protection voltage
Difference between
typical and impulse
voltage
Overcurrent protection technologies may be
summarized as follows:
• PTC thermistors provide self-resetting protection.
• Fuses provide good overload capability and low
resistance.
• Heat coils protect against lower level ‘sneak currents’.
Typical AC protection
voltage
Figure 3. Systems must survive more than the
nominal protection voltage
20
• LFRs provide the most fundamental level of
protection, combined with the precision resistance
values needed for balanced lines and are often
combined with other devices.
Thyristor). A series or shunt combination of clamping and switching type devices may provide a better
solution than a single technology.
Reliability Tip
Check worst-case protection values, not just
nominal figures.
Technology Selection - Overvoltage Protectors
Voltage limiting devices reduce voltages that exceed
the protector threshold voltage level. The two basic
types of surge protective devices are clamping and
switching, Figure 8. Clamping type protectors have a
continuous voltage-current characteristic (MOV and
TVS), while the voltage-current characteristic of the
switching type protector is discontinuous (GDT and
Utilize the decision trees in Figures 4-7 to aid in the
selection of a suitable circuit protection solution.
Comparative performance indicators and individual
device descriptions beneath each decision tree allow
designers to evaluate the relative merits for each
individual or combination of technologies.
The lower density and increased exposure of rural
sites suggests that heavier surges can be expected for
Uncontrolled
environment?
No
Yes
Solution?
Thyristor
Hybrid?
TVS
Thyristor
Diode
Thyristor
GDT
No
CLAMP?
MOV
GDT +
TVS
GDT +
MOV
Lower impulse voltage
Lower capacitance
MOV
Yes
CLAMP?
GDT +
MOV
GDT
TVS
GDT +
TVS
Lower impulse voltage
Lower capacitance
Lower capacitance
Long impulse life
Lowest
Impulse
Voltage
Hybrid?
Long impulse life
Highest Intrinsic Impulse Capability
Note: The overvoltage protector may require the addition of AC overcurrent protection.
Figure 4. Primary overvoltage technology selection
What component
type is being
protected?
Passive
Active/
Semiconductor
See Figure 6
See Figure 7
Figure 5. Secondary overvoltage protection depends
on the type of component to be protected
these applications (Figure 4), while the cost and type
of the protected equipment has an influence on the
selection of secondary protection (Figure 5, 6, & 7).
During the operation of overvoltage protectors,
surge currents can be very high and PCB tracks
and system grounding regimes must be properly
dimensioned.
Reliability Tip
Ensure that PCB tracks and wiring are dimensioned
for surge currents.
21
ISDN and xDSL. Matched and stable devices are
necessary to avoid introducing imbalance in the
system.
Passive
Resistor
Component type?
Solution?
GDT
Protection
Thyristor
Increased
rating
Thyristor
Inductive
Lower cost
Thyristor
TVS
Component
Increased
rating
GDT
Gas Discharge Tubes (GDTs)
Smaller
GDTs apply a short circuit under surge conditions,
returning to a high impedance state after the surge.
These robust devices with negligible capacitance are
attractive for protecting digital lines. GDTs are able
to handle significant currents, but their internal
design can significantly affect their operating life
under large surges (see Figure 9). GDTs are sensitive
to the rate of rise of voltage surges (dv/dt), which
increase the Sparkover Voltage under fast impulse
conditions up to double that of AC conditions.
Their ability to handle very high surge currents for
hundreds of microseconds and high AC for many
Transformer
Class?
Solution?
Protection
Protection
Lower cost
Inductor
Protection
Datasheet Tip
When protecting digital lines, check the tolerance
and variation of protection capacitance (i.e. voltage
dependance), not just nominal values.
Solution?
Thyristor
Smaller
Capacitor
Solution?
Component
Protection
Increased
rating
Thyristor
Protection
GDT
Component
Increased
rating
Note: The overvoltage protector may require the addition of AC
overcurrent protection.
Figure 6. Secondary protection of passive components
It is important that protectors do not
interfere with normal operation.
Although traditional telecom systems
typically run at –48 V battery voltage
plus 100 V rms ringing voltage (i.e.
approximately 200 V peak), designers
should consider worst-case battery
voltage, device temperature, and power
induction voltages when specifying
minimum protection voltage. Some
digital services operate at much higher
span voltages, requiring further consideration for equipment designed for
broadband applications (see Table 3 in
the Applications section).
The capacitance of overvoltage protectors
connected across these lines is important especially for digital connections such as
22
Active/
Semiconductor
Thyristor
SLIC
Component type?
PSU
Solution?
Xpoint Switch
LCAS, SSR
Solution?
Diode
Bridge
Hybrid
AC Capability
Thyristor
TVS
AC Capability
Protection level
Lower cost
Thyristor
MOV
AC Capability
Protection level
Xpoint Switch: Cross-point Switch
LCAS: Line Card Access Switch
PSU: Power Supply Unit
SSR: Solid State Relay
SLIC: Subscribe Line Interface Circuit
Note: The overvoltage protector may require the addition of AC overcurrent
protection, such as a LFM, PTC thermistor or fuse.
Figure 7. Secondary protection of active components
Certain GDTs can suffer
from venting or gas loss. To
ensure protection under
these circumstances, an air
Back Up Gap (BUG) has
been used. BUGs themselves
can be subject to moisture
ingress or contamination,
reducing their operating
voltage, and leading to nuisance tripping. BUGs are
also more sensitive to fast
rising voltage surges, causing
the BUG to operate instead
of the GDT. All Bourns
GDTs are now UL approved
for use without the need of
a BUG, eliminating extra
cost and improving reliability
(see Figure 10).
100
MOV
A
TVS
10
GDT
Current
1
mA
GDT
Thyristor
100
10
Thyristor
1
0
100
GDT
200
300
400
500
Voltage - V
Figure 8. Overvoltage protectors feature very different V/I characteristics
450
GDT DC Sparkover Voltage Variation over Impulse Life
(350 V GDTs)
400
DC Sparkover Voltage @ 100 V/s
350
300
Bourns
Supplier A
Supplier B
Supplier C
Supplier D
250
200
150
Standards Tip
UL Recognized GDTs are
now available,
requiring no BUG.
100
50
0
Datasheet Tip
GDTs are available with
Switch-Grade Fail-Short
Device.
50
100
150
200
250
300
Number of 500 A, 10/1000 impulses
Figure 9. GDT behavior may deteriorate under
real-world field conditions
seconds matches the primary protection needs of
exposed and remote sites. During prolonged AC
events, GDTs can develop very high temperatures,
and should be combined with a thermal overload
switch that mechanically shorts the line (SwitchGrade Fail-Short mechanism).
350
400
Bourns Products
Bourns offers the subminiature 3-electrode
Mini-TRIGARD® and the 2-electrode Mini-GDT.
Combining small size with the industry’s best
impulse life, these products are ideal for high-density
primary applications.
23
Surge
Current
Several kA
for 100 µs
Power
Cross
Several amps
for seconds
dv/dt
Sensitivity
Poor
di/dt
Sensitivity
None
GDT protection capabilities
GDT Selected
No
GDT UL
Recognized
GDT +
BUG
Yes
GDT
Reliability
to handle moderate
currents without a
wear-out mechanism.
The disadvantages of
Primary and secondary
protection
thyristor protectors are
Exposed sites
higher capacitance,
Sensitive equipment needs
which is a limitation in
additional secondary
high-speed digital
protection
applications, and less
Particularly suited to high
tolerance of excessive
speed digital lines
current. Thyristor
protectors can act either as secondary protection in
conjunction with GDTs, or as primary protection for
more controlled environments/ lower surge amplitudes. For protection in both voltage polarities,
either a power diode or second thyristor may be
integrated in inverse parallel, creating versatile protection functions that may be used singly or in various
combinations. The clamping voltage level of fixed
voltage thyristors is set during the manufacturing
process. Gated thyristors have their protective level
set by the voltage applied to the gate terminal.
Typical Application
UL Recognized GDTs no longer need a BUG (air Back Up Gap)
Bourns Products
Figure 10. Traditional GDT venting has required
back-up protection
Thyristor-Based Devices
Thyristor-based devices initially clamp the line voltage,
then switch to a low-voltage “On” state. After the
surge, when the current drops below the “holding
current,” the protector returns to its original high
impedance state. The main benefits of thyristor
protectors are lower voltage overshoot and an ability
Surge
Current
Power
Cross
Several 100 A Several amps
for 100 µs
for seconds
dv/dt
Sensitivity
Good
di/dt
Sensitivity
Poor
The TISP® family of thyristor-based devices includes
an extensive range of single and multiple
configurations in unidirectional and bidirectional
formats, with fixed or gated operation.
Metal Oxide Varistors (MOVs)
A Metal Oxide Varistor (variable resistor) is a voltage
dependent resistor
whose current predomTypical Application
inantly increases
exponentially with
Primary or secondary
increasing voltage.
protection
Urban and some exposed sites
In clamping surges,
the MOV absorbs a
substantial amount of
the surge energy. With a high thermal capacity, MOVs
Can protect sensitive
equipment
Thyristor protection capabilities
24
have high energy and current capability in a relatively
small size. MOVs are extremely fast and low cost, but
have high capacitance, a high, current-dependant
clamping voltage, and are susceptible to wear.
controlled voltage clamp enables the selection of
protection voltages closer to the system voltage,
providing tighter protection.
Technology Selection - Overcurrent Protectors
Current limiting
devices (See Figures
Typical Application
11, 12) provide a slow
response, and are
Several kA
Dissipation
Good
Secondary protection
primarily aimed at
for 100 µs
limited
Can protect non-sensitive equipment
protection from surges
lasting hundreds of
MOV protection capabilities
milliseconds or more, including power induction or
contact with AC power. By combining a fixed resistor
in series with a resettable protector, an optimum
Typical MOV applications include general-purpose
balance of nominal resistance and operating time is
AC protection or low-cost analog telecom equipment
obtained. The inherent resistance of certain overcursuch as basic telephones. When combined with a
rent protectors can also be useful in coordination
GDT, the speed of the MOV enables it to clamp the
between primary and secondary overvoltage
initial overshoot while the GDT begins to operate.
protection.
Once the GDT fires, it limits the energy in the MOV,
Surge
Current
Power
Cross
dv/dt
Sensitivity
AC Overcurrent
reducing the size of MOV required. Devices are
available which integrate an MOV and GDT in a
single package to simplify assembly and save space.
Primary overvoltage
technology?
Thyristor
Datasheet Tip
When selecting operating voltage, remember that
MOV residual voltage increases considerably at
higher current.
Solution?
Mechanical
compression
Transient Voltage Suppressors
Transient Voltage Suppressor (TVS) diodes are
sometimes called Zeners, Avalanche or Breakdown
Diodes, and operate by rapidly moving from high
impedance to a non-linear resistance characteristic
that clamps surge voltages. TVS diodes provide a
fast-acting and well-controlled clamping voltage
which is much more precise than in an MOV,
but they exhibit high
Surge
Power
capacitance and low
Current
Cross
energy capability,
restricting the maximum Low
Poor
surge current. Typically
used for low power
applications, their well-
GDT
Solution?
Solder
melt
Mechanical
switch*
Solder
melt
Insulation
melt
Lower cost
Lower on resistance
High current impulse
Lower fire risk
Lower cost
*Switch-Grade Fail-Short
Note: Protection against sneak currents requires the additional
components
Figure 11. Selection of fail-short technology for
Primary overvoltage protection
dv/dt
Sensitivity
None
Typical Application
Secondary protection
Can protect sensitive equipment
TVS protection capabilities
25
Yes
No
Resettable
Use with
ADSL?
Sneak current
protection needed?
No
Yes
PTC thermistor
type?
No
Heat coil
Polymer
Ceramic
Straightthrough
Lower signal loss
Better line balance
Polymer PTC devices typically have a lower resistance
than ceramic and are stable with respect to voltage
and temperature. After experiencing a fault condition,
a change in initial resistance may occur. (Resistance
is measured one hour after the fault condition is
removed and the resulting change in resistance compared to initial resistance is termed the R1 jump.)
In balanced systems with a PTC thermistor in each
conductor, resistance change may degrade line balance. Including additional series resistance such as
an LFR can reduce the effect of the R1 jump. In
addition, some PTC thermistors are available in
resistance bands to minimize R1 effects. Polymer
types are also commonly used singly to protect CPE
equipment.
Figure 12. Sneak current technology selection
Reliability Tip
Hybrid devices incorporating resistors can improve
performance.
Positive Temperature Coefficient (PTC) Thermistors
Heat generated by current flowing in a PTC thermistor
causes a step function increase in resistance towards
an open circuit, gradually returning close to its
original value once the current drops below a threshold value. The stability of resistance value after
surges over time is a key issue for preserving line
balance. PTCs are commonly referred to as resettable
fuses, and since low-level current faults are very
common, automatically resettable protection can be
particularly important. There are two types of PTC
thermistors based on
different underlying
Nominal
Ohms
materials: Polymer and
Ceramic. Generally the
device cross-sectional
Polymer PTC
0.01 - 20
area determines the
Thermistor
surge current capability,
Ceramic PTC
10 - 50
and the device thickness Thermistor
determines the surge
voltage capability.
Ceramic PTC devices do not exhibit an R1 jump,
and their higher resistance avoids the need for
installing an additional LFR. While this reduces
component count, the resistance does vary with
applied voltage. Since this change can be substantial
(e.g. a decrease by a factor of about 3 at 1 kV), it is
essential that any secondary overvoltage protection
be correctly rated to handle the resulting surge current, which can be three times larger than predicted
by the nominal resistance of the ceramic PTC. In a
typical line card application, line balance is critical.
Reliability Tip
The stability of PTC thermistor resistance after
operation can be critical for line balance.
Resistance
Stability
(with V
and
Temperature)
Change
After
Surge
Good
10-20 %
R decreases
with temperature
and under
impulse
Small
Typical
Application
CPE Equipment,
e.g. Modem
Balanced line,
e.g. Line Card SLIC
Table 4. The two types of PTC thermistors have important differences
26
Datasheet Tip
PTC thermistor and resistor hybrids can improve speed
and line balance.
rupture under excess current conditions or separate
components, it is also possible to produce hybrid
fusible resistors.
Bourns Products
Bourns Products
Bourns offers an extensive range of polymer PTC devices
in the Multifuse® resettable fuse product family,
providing resettable overcurrent protection solutions.
Telefuse™
Telecom Fuses
Bourns has recently launched the B1250T/B0500T
range of SMT power fault protection fuses.
Heat Coils
Fuses
A fuse heats up during surges, and once the temperature of the element exceeds its melting point, the
normal low resistance is converted to an open circuit.
The low resistance of fuses is attractive for xDSL
applications, but their operation is relatively imprecise and time-dependant. Once operated, they do not
reset. Fuses also require additional resistance for
primary coordination (see Application section).
Since overvoltage protection usually consists of
establishing a low impedance path across the equipment input, overvoltage protection itself will cause
high currents to flow. Although relatively slow acting,
fuses can play a major safety role in removing longerterm faults that would damage protection circuitry,
thus reducing the size and cost of other protection
elements. It is important to consider the I-t performance of the selected fuse, since even multiples of the
rated current may not cause a fuse to rupture except
after a significant delay. Coordination of this fuse
behavior with the I-t performance of other protection
is critical to ensuring that there is no combination of
current-level and duration for which the protection
is ineffective. By including structures intended to
Safety Tip
Fuses offer a simple way to remove long-term faults,
and potentially dangerous heat generation,
but I-t coordination with other protection is vital.
Heat coils are thermally activated mechanical devices
connected in series with the line being protected,
which divert current to ground. A series coil operates
a parallel shunt contact, typically by melting a solder
joint that is restraining a spring-loaded contact.
When a current generates enough heat to melt the
joint, the spring mechanically forces two contacts
together, short-circuiting the line. Heat coils are
ideal to protect against “sneak currents” that are too
small to be caught by other methods. Their high
inductance makes them unsuitable for digital lines.
It is also possible to construct current interrupting
heat coils which go open circuit as a result of
overcurrent.
Line Feed Resistors
A Line Feed Resistor (LFR) is the most fundamental
form of current protection, normally fabricated as a
thick-film device on a ceramic substrate. With the
ability to withstand high voltage impulses without
breaking down, AC current interruption occurs
when the high temperature developed by the resistor
causes mechanical expansion stresses that result in
the ceramic breaking open. Low current power
induction may not break the LFR open, creating
long-term surface temperatures of more than 300 °C.
To avoid heat damage to the PCB and adjacent
components, maximum surface temperature can be
limited to about 250 °C by incorporating a series
thermal link fuse on the LFR. The link consists of a
solder alloy that melts when high temperatures occur
for periods of 10 seconds or more. Along with the
high precision needed for balanced lines, LFRs have
27
significant flexibility to integrate additional resistors,
multiple devices, or even different protection technology within a single component. One possible
limitation is the need to dimension the LFR to handle
the resistive dissipation under surge conditions.
Along with combining multiple non-inductive
thick-film resistors on a single substrate to achieve
matching to <1 %, a resistor can be combined with
other devices to optimize their interaction with the
overall protection design. For example, a simple
resistor is not ideal for protecting a wire, but combining a low value resistor with another overcurrent
protector provides closer protection and less
dissipation than either device can offer alone. Both
functions can be integrated onto a single thick-film
component using fusible elements, PTC thermistors,
or thermal fuses. Similarly, more complex hybrids
are available, adding surface mount components
such as thyristor protectors, to produce coordinated
sub-systems.
limiting device. When the plastic melts, the spring
contacts both conductors and shorts out the voltagelimiting device.
A solder–pellet-melting based switch consists of a
spring mechanism that separates the line conductor(s)
from the ground conductor by a solder pellet. In the
event of a thermal overload condition, the solder
pellet melts and allows the spring contacts to short
the line and ground terminals of the voltage-limiting
device.
A “Snap Action” switch typically uses a spring
assembly that is held in the open position by a
soldered standoff and will short out the voltagelimiting device when its switching temperature is
reached. When the soldered connection melts, the
switch is released and shorts out the line and ground
terminals of the voltage limited (Bourns US Patent
#6,327,129).
Modes of Overvoltage Protection
Bourns Products
Surge
Line Protection Modules
Bourns offers Line Feed Resistors combining matched
resistor pairs plus thermal link fuses.
Thermal Switches
These switches are thermally activated, non-resetting
mechanical devices mounted on a voltage-limiting
device (normally a GDT). There are three common
activation technologies: melting plastic insulator,
melting solder pellet or a disconnect device. Melting
occurs as a result of the temperature rise of the
voltage-limiting device’s thermal overload condition
when exposed to a continuous current flow. When
the switch operates, it shorts out the voltage-limiting
device, typically to ground, conducting the surge
current previously flowing through the voltagelimiting device.
A plastic-melting based switch consists of a spring
with a plastic insulator that separates the spring
contact from the metallic conductors of the voltage-
28
Insufficient protection reduces reliability, while
excessive protection wastes money, making it vital to
match the required protection level to the equipment
or component being protected. One important
aspect is the “modes” of protection. Figure 13 illustrates that, for two wire systems, a single mode of
operation protects against transverse (differential/
metallic) voltages, but for three wire systems, the
ground terminal provides opportunities to protect
against both transverse and longitudinal (commonmode) surges. This offers a trade-off for items such
as modems, where the provision of adequate insulation to ground for longitudinal voltages enables
simple single mode/single device protection to be
used. Ground-referenced SLICs and LCAS ICs,
however, require three-mode protection.
Figure 14 illustrates how devices may be combined
and coordinated to offer three-mode protection.
The three-wire GDT offers two modes of robust
primary protection, while two PTC devices provide
decoupling and coordination. The bi-directional
thyristor provides the third mode of precise secondary
voltage protection.
Protection
Modes
Protection
Modes
Protection
Modes
Protection
Modes
1
1
1
1
2
2
2
2
PA
Pb Pc
PA
PC
One Protector
One Mode
PB
Two Protectors
Two Modes
PC
PB
Three Protectors
Three Modes
Delta (∆) Connected
Pa
Three Protectors
Three Modes
Wye (Y) Connected
Figure 13. Matching the modes of protection to the application optimizes protection and cost
R1
+t °
GDT1
Th1
overvoltage protectors and a broader combination of
overvoltage and overcurrent protection integrated
line protection modules are presented.
R2
Multi-Stage Protectors
+t °
Wire to Ground
GDT
Inter-Wire
Thyristor
Figure 14. The modes of protection may be split between primary and secondary devices,with
PTC thermistors ensuring coordination
Technology Selection - Integrated Solutions
As emphasized earlier, no single technology provides
ideal protection for all requirements. Combining
more than one technology can often provide an
attractive practical solution. Clearly the convenience
of a single component/module combining multiple
devices saves space and assembly cost while
simplifying the design task (see Figure 15). In addition, some integrated modules provide performance
and capabilities that cannot be achieved with separate
discrete devices. In the next sections, multi-stage
4B06
0205 B-540-1
25/21
Figure 15. Photo of hybrid
9
When considering overvoltage protection (see Figure
4), combining a GDT with either a TVS or MOV
clamping device can reduce the impulse voltage
stress seen by downstream components. Although
TVS devices are attractive, they often introduce too
much capacitance. Typically, a GDT/MOV combination offers a better solution. Figure 16 illustrates the
different behavior of GDTs, GDT/MOV hybrids and
Thyristor overvoltage protection for both 100 V/µs
and 1000 V/µs impulse waveforms. The GDT/MOV
hybrid provides more consistent protection than a
simple GDT, irrespective of the environment.
The low capacitance of the GDT/MOV hybrid also
provides valuable characteristics for high frequency
applications, enabling the protection of a wide range
of copper-pair lines from POTS to VDSL and CAT5
100 Mb/s networks. All Bourns‚ GDT and GDT/MOV
hybrid families are UL Recognized for use without a
BUG, making them simple to use and saving valuable
space. In addition to its superior clamping of fast
rising transients, the MOV of the GDT/MOV
assembly provides the function of a back up device
without the well-known negative side effects of
BUGs. Figure 11 demonstrates that a thermally operated current diverter is useful to protect the GDT
29
from excessive heat dissipation under prolonged
power cross conditions. The best performance and
lowest fire risk are provided by the thermal switch or
switch-grade fail-short mechanism. GDT/MOV/failshort overvoltage protectors effectively replace three
components, providing maximum surge current
capability from the GDT, low transient clamping
characteristics and back up function from the MOV,
and maximum safety from the switch-grade failshort device.
8 mm GDT
8 mm GDT Hybrid
Thyristor
1000
700
500
400
300
Although PTC thermistors may be used alone, series
connection with an LFR reduces peak currents and
1000 V/µs
200
150
SMT Fuse
2-point
LFR
1000 V/µs
3-point “V”
20
15
LFR +
Thermal Link Fuse
10
150
200
250
300
350
400
450
Maximum System Voltage – V
(GDT – Minimum Sparkover)
(Thyristor VDRM)
Figure 16. Each protection technology behaves
differently under Impulse conditions
Bourns Products
The Bourns MSP® Multi-Stage Protector assembly
combines MOV responsiveness with GDT robustness.
Combined with our patented switch-grade fail-short
device, it provides the optimum broadband network
primary protection solution.
3-point Gated
500
+t °
PTC Thermistor
3-point “Y”
Resistor Array
+t °
LFR +
PTC Thermistor
3-point “Delta”
Resistor
Array
100
Overvoltage
Protection
50
30
Overvoltage Protection
Overcurrent
Protection
100 V/µs
100
70
50
40
30
Integrating multiple protection elements on a single
FR4 or ceramic substrate SIP reduces the PCB area
taken and increases the number of lines that can be
fitted to each line card. Figure 17 outlines the key
technologies available for such integrated assemblies
and introduces one new form of overcurrent protection. Thermal Link Fuses use the heat from the LFR
under continuous power induction to desolder a
series link, which interrupts the induced current,
avoiding thermal damage to the module, the line
card or surrounding components. They are not practical as discrete devices because they use special
structures built into the substrate. These integrated
modules tend to be customized for each application,
rather than off-the-shelf components.
Overcurrent
Protection
Normalized Impulse or Ramp Protection Voltage Increase – %
Impulse and Ramp % Voltage Increase
vs
Maximum System Voltage
Integrated Line Protection Modules
Line 1 circuit
SIP LPM
Line n circuit
Figure 17. Multiple technologies may be integrated
into a single, space-saving Line Protection
Module
thereby allows smaller cross-section PTC thermistors
to be used. The thermal coupling of an integrated
module also ensures that the LFR heating further
increases the rate of PTC thermistor temperature rise
during AC faults causing faster low current tripping.
The series LFR resistance will reduce the impulse
current increase of ceramic thermistors and reduce
the relative trip resistance change of polymer types.
It is worth noting that 10 mm SMT microfuses are
now available (e.g. Bourns Telefuse™) with 600 V
ratings to meet GR-1089-CORE, and UL 60950 safety
requirements, and, dependent on application, these
may be fitted in either one or both signal lines. LFR
technology can also be used to fabricate precision
high voltage resistors on the same substrate for
non-protection use, such as power ring feed resistors
and bridges for off-hook detection, giving further
cost and PCB space savings.
As seen in “Modes of overvoltage protection”, it is
important to match the protection topology (typically
thyristor based) to the equipment being protected,
with simple single-mode, 2-point protection being
suitable for Tip to Ring protection applications such
as modem coupling capacitor protection. The twomode bidirectional 3-point “V” is a common configuration, protecting components connected between
Tip or Ring and Ground, while SLICs powered from
negative supplies need only a unidirectional 3-point
“V”. Three-mode “Y” or “Delta” 3-point protection is
used where protection is needed both to ground and
inter-wire.
Figure 18 illustrates an LCAS protection module,
with ±125 V Tip protection, and ±219 V Ring
protection in a 3-point “V” configuration, complete
with LFRs and thermal link fuses.
4B06B-540-125/219 LPM
for LCAS Protection
F1
R1
R2
F2
Th1
Th2
R1 = 10 Ω
R2 = 10 Ω
F1 = Thermal Link Fuse
F2 = Thermal Link Fuse
Th1= TISP125H3BJ
Th2= TISP219H3BJ
Figure 18. An example of an LPM integrated LCAS
protection module
conditions. Further, the thyristor long-term temperature rise is constrained to the trip temperature of the
thermistor, thereby limiting the maximum protection
voltage under low AC conditions.
Each module can provide multiple circuits, protecting
2, 4 or 6 lines with a single module. The use of UL
Recognized components greatly eases both consistency
of performance and UL recognition of the module.
System-level design is simplified, because individual
component variations are handled during the module
design, enabling the module to be considered as
a network specified to withstand defined stress
levels at the input, while passing known stresses to
downstream components.
Bourns Products
Surge
Line Protection Modules
Bourns offers a variety of Line Protection Module (LPM)
products, including custom options.
As with discrete device solutions, gated thyristor
protectors can be used to significantly reduce voltage
stress for sensitive SLICs and current stress on downstream protection circuits. Once again the thermal
coupling between a PTC thermistor and a heating
element is beneficial. Heat from the thyristor speeds
up thermistor tripping under power induction
31
Selection Guide
GDT Operation
•
•
•
•
•
•
•
•
Very high surge handling capability
Extremely low work function for long service life
Low capacitance & insertion loss
Highly symmetrical cross-ionization
Non-radioactive materials
Optional Switch-Grade Fail-Short
“Crowbar” function to less than 10 V arc voltage
Telcordia, RUS, ITU-T, IEC, IEEE and UL
compliant
• Broadband network capable
• Through-hole, SMT and cassette mounting types
available
• Surge Protector Test Set (Model 4010-01) available
for GDTs and other technologies
Bourns® GDTs prevent damage from transient
disturbances by acting as a “crowbar”, i.e. a short
circuit. When an electrical surge exceeds the GDT’s
defined sparkover voltage level (surge breakdown
voltage), the GDT becomes ionized, and conduction
takes place within a fraction of a microsecond. When
the surge passes and the system voltage returns to
normal levels, the GDT returns to its high-impedance
(off) state.
Bourns GDT Features
• Unmatched performance and reliability
• Various lead configurations
• Smallest size in the industry (Mini 2-Pole and
MINI TRIGARD™)
DC
Sparkover
Voltage
No. of
of
Electrodes
Dimensions
(Dia. x Length)
Max.
Single
Surge
Rating
(8/20 µs)
2026-07
2026-09
2026-15
2026-20
2026-23
2026-25
2026-30
2026-35
2026-40
2026-42
2026-47
2026-60
75 V
90 V
150 V
200 V
230 V
250 V
300 V
350 V
400 V
420 V
470 V
600 V
3
8 mm x 11.2 mm
40 kA
2036-07
2036-09
2036-15
2036-20
2036-23
2036-25
2036-30
2036-35
2036-40
2036-42
2036-47
2036-60
75 V
90 V
150 V
200 V
230 V
250 V
300 V
350 V
400 V
420 V
470 V
600 V
3
5 mm x 7.5 mm
20 kA
Model
Max.
Surge
Rating
(8/20 µs)
SwitchGrade
Fail-Short
Operation
Capacitance
Min. Surge
Life Rating
(10/1000 µs
waveshape)
10 x 20 kA 10 x 20 A rms,
1s
Yes
<2 pF
400 x 1000 A
10 x 10 kA 10 x 10 A rms,
1s
Yes
<2 pF
500 x 200 A
Max.
AC
Rating
The rated discharge current for 3-Electrode GDTs is the total current equally divided between each line to ground.
32
DC
Sparkover
Voltage
No. of
of
Electrodes
Dimensions
(Dia. x Length)
Max.
Single
Surge
Rating
(8/20 µs)
2027-09
2027-15
2027-20
2027-23
2027-25
2027-30
2027-35
2027-40
2027-42
2027-47
2027-60
90 V
150 V
200V
230 V
250 V
300 V
350 V
400 V
420 V
470 V
600 V
2
8 mm x 6 mm
25 kA
2037-09
2037-15
2037-20
2037-23
2037-25
2037-30
2037-35
2037-40
2037-42
2037-47
2037-60
90 V
150 V
200 V
230 V
250 V
300 V
350 V
400 V
420 V
470 V
600 V
2
5 mm x 5 mm
2035-09
2035-15
2035-20
2035-23
2035-25
2035-30
2035-35
2035-40
2035-42
2035-47
2035-60
90 V
150 V
200 V
230 V
250 V
300 V
350 V
400 V
420 V
470 V
600 V
2
2026-23-xx-MSP
2026-33-xx-MSP
230 V
330 V
3
Model
Max.
Surge
Rating
SwitchGrade
Fail-Short
Operation
Capacitance
10 x 10 kA 10 x 10 A rms,
1s
N/A
<1 pF
500 x 500 A
10 kA
10 x 5 kA
10 x 5 A rms,
1s
N/A
<1 pF
500 x 100 A
5 mm x 4 mm
10 kA
10 x 5 kA
10 x 5 A rms,
1s
N/A
<1 pF
500 x 100 A
8 mm x 14 mm
40 kA
10 x 20 kA 20 x 10 A rms, Standard
1s
<20 pF
1000 x 1000 A
Max.
AC
Rating
Min. Surge
Life Rating
(10/1000 µs
MSP® = Multi-Stage Protection
The rated discharge current for 3-Electrode GDTs is the total current equally divided between each line to ground.
33
Selection Guide
Bourns’ range of Multifuse® Polymer PTCs have
been designed to limit overcurrents in telecommunication equipment as well as many other types of
equipment. Adequate overcurrent protection is
needed to allow equipment to comply with
international standards. Overcurrents can be caused
Product
Series
Part
Number
MF-R/90
R0
12255
0T
MF-R/250
MF-SM/250
MF-D/250
Vmax
(V)
Ihold
(A)
Imax
(I)
Rmin
(Ω)
Rmax
(Ω)
R1max
(Ω)
Pd
(W)
Telecom
Standards
MF-R055/90
MF-R055/90U
MF-R075/90
90
90
90
0.55
0.55
0.75
10.0
10.0
10.0
0.450
0.450
0.370
0.900
0.900
0.750
2.000
2.000
1.650
2.00
2.00
2.00
N/A
MF-R008/250
MF-R011/250
MF-R012/250
MF-R012/250-A
MF-R012/250-C
MF-R012/250-F
MF-R012/250-1
MF-R012/250-2
MF-R012/250-80
MF-R014/250
MF-R014/250-A
MF-R014/250-B
MF-R018/250
250
250
250
250
250
250
250
250
250
250
250
250
250
0.08
0.11
0.12
0.12
0.12
0.12
0.12
0.12
0.12
0.14
0.14
0.14
0.18
3.0
3.0
3.0
3.0
3.0
3.0
3.0
3.0
3.0
3.0
3.0
3.0
10.0
14.000
5.000
4.000
7.000
5.500
6.000
6.000
8.000
4.000
3.000
3.000
4.500
0.800
20.000
9.000
8.000
9.000
7.500
10.500
9.000
10.500
8.000
6.000
5.500
6.000
2.000
33.000
16.000
16.000
16.000
16.000
16.000
16.000
16.000
16.000
14.000
12.000
14.000
4.000
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
ITU-T K.20/21/45
MF-SM013/250
MF-SM013/250-A
MF-SM013/250-B
MF-SM013/250-C
MF-SM013/250-D
MF-SM013/250V
250
250
250
250
250
250
0.13
0.13
0.13
0.13
0.13
0.13
3.0
3.0
3.0
3.0
3.0
3.0
6.000
6.500
9.000
7.000
7.000
4.000
12.000
9.000
12.000
10.000
9.000
7.000
20.000
20.000
20.000
20.000
20.000
20.000
3.00
3.00
3.00
3.00
3.00
3.00
ITU-T K.20/21/45
MF-D008/250
MF-D011/250
MF-D012/250
MF-D013/250
MF-D014/250
MF-D018/250
250
250
250
250
250
250
0.08
0.11
0.12
0.13
0.14
0.18
3.0
3.0
3.0
3.0
3.0
10.0
14.000
5.000
4.000
6.000
3.000
0.800
20.000
9.000
8.000
12.000
6.000
2.000
33.000
16.000
16.000
20.000
14.000
4.000
1.00
1.00
1.00
1.00
1.00
1.00
ITU-T K.20/21/45
Device Options:
• Coated or Uncoated
• Un-Tripped or Pre-Tripped
• Narrow resistance bands
34
by AC power or lightning flash disturbances that are
induced or conducted on to the telephone line. Our
extensive range offers multiple voltage variants to
suit specific application requirements. Our devices
are available in surface mount, radial, disk and strap
type packages.
• Custom specified resistance bands
• Resistance sort to 0.5 ohm bins
• Disks with and without solder coating
Packaging Options:
• Bulk packed
• Tape and reel
• Custom lead lengths
GR-1089
Intrabuilding
GR-1089
Intrabuilding
GR-1089
Intrabuilding
Selection Guide
Our world-class TISP® Thyristor Surge Protectors are
designed to limit overvoltages on telephone lines.
Adequate overvoltage protection is needed to allow
equipment to comply with international standards.
Overvoltages can be caused by AC power or lightning
flash disturbances that are induced or conducted on
to the telephone line. Our extensive range offers
multiple voltage variants to suit specific application
requirements. Our devices are available in surfacemount or through-hole packages and are guaranteed
to withstand international lightning surges.
TISP1xxx Series - Dual Unidirectional Overvoltage Protectors
Delivery
Options
Device
TISP1072F3
TISP1082F3
DR, P, SL
DR, P, SL
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
58
66
72
82
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
ANSI C62.41
ITU-T K.20/45/21
2/10 µs
10/1000 µs
8/20 µs
5/310 µs
A
A
A
A
80
80
35
35
70
70
50
50
TISP3xxx Series - Dual Bidirectional Overvoltage Protectors
Delivery
Options
Device
TISPL758LF3
TISP3072F3
TISP3082F3
TISP3125F3
TISP3150F3
TISP3180F3
TISP3240F3
TISP3260F3
TISP3290F3
TISP3320F3
TISP3380F3
TISP3600F3
TISP3700F3
DR
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
SL
SL
TISP3070H3
TISP3080H3
TISP3095H3
TISP3115H3
TISP3125H3
TISP3135H3
TISP3145H3
TISP3180H3
TISP3210H3
TISP3250H3
TISP3290H3
TISP3350H3
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
ANSI C62.41
ITU-T K.20/45/21
2/10 µs
10/1000 µs
8/20 µs
5/310 µs
A
A
A
A
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
105, 180
58
66
100
120
145
180
200
220
240
270
420
500
130, 220
72
82
125
150
180
240
260
290
320
380
600
700
175
80
80
175
175
175
175
175
175
175
175
190
190
35
35
35
35
35
35
35
35
35
35
35
45
45
120
70
70
120
120
120
120
120
120
120
120
175
175
50
50
50
50
50
50
50
50
50
50
50
70
70
58
65
75
90
100
110
120
145
160
190
220
275
70
80
95
115
125
135
145
180
210
250
390
350
500
500
500
500
500
500
500
500
500
500
500
500
100
100
100
100
100
100
100
100
100
100
100
100
300
300
300
300
300
300
300
300
300
300
300
300
200
200
200
200
200
200
200
200
200
200
200
200
35
TISP3xxx Series - Dual Bidirectional Overvoltage Protectors (Continued)
Device
TISP3070T3
TISP3080T3
TISP3095T3
TISP3115T3
TISP3125T3
TISP3145T3
TISP3165T3
TISP3180T3
TISP3200T3
TISP3219T3
TISP3250T3
TISP3290T3
TISP3350T3
TISP3395T3
Delivery
Options
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
58
65
75
90
100
120
135
145
155
180
190
220
275
320
70
80
95
115
125
145
165
180
200
219
250
290
350
395
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
ANSI C62.41
ITU-T K.20/45/21
2/10 µs
10/1000 µs
8/20 µs
5/310 µs
A
A
A
A
250
250
250
250
250
250
250
250
250
250
250
250
250
250
80
80
80
80
80
80
80
80
80
80
80
80
80
80
250
250
250
250
250
250
250
250
250
250
250
250
250
250
120
120
120
120
120
120
120
120
120
120
120
120
120
120
TISP4xxxF3 Series (35 A 10/1000 µs, 150 mA IH) - Single Bidirectional Overvoltage Protectors
IPPSM Ratings for Lightning Surge Standards
Delivery
Options
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
LM, LMR, LMFR
58
66
100
120
145
180
200
220
240
270
420
500
72
82
125
150
180
240
260
290
320
380
600
700
Device
TISP4072F3
TISP4082F3
TISP4125F3
TISP4150F3
TISP4180F3
TISP4240F3
TISP4260F3
TISP4290F3
TISP4320F3
TISP4380F3
TISP4600F3
TISP4700F3
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
80
80
175
175
175
175
175
175
175
175
190
190
35
35
35
35
35
35
35
35
35
35
45
45
TIA/EIA-IS-968
(FCC PART 68)
10/560 µs
A
ITU-T K.20/45/21
5/310 µs
A
60
60
60
60
60
60
60
60
60
60
110
110
50
50
50
50
50
50
50
50
50
50
70
70
TISP4xxxLx Series (30 A 10/1000 µs, 50 & 150 mA IH) - Single Bidirectional Overvoltage Protectors
IPPSM Ratings for Lightning Surge Standards
Device
36
Delivery
Options
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
Holding
Current
IH
mA
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
TIA/EIA-IS-968
(FCC PART 68)
10/560 µs
A
ITU-T K.20/45/21
5/310 µs
A
TISP4015L1
TISP4030L1
TISP4040L1
AJR, BJR
AJR, BJR
AJR, BJR
8
15
25
15
30
40
50
50
50
150
150
150
30
30
30
35
35
35
45
45
45
TISP4070L3
TISP4080L3
TISP4090L3
TISP4125L3
TISP4145L3
TISP4165L3
TISP4180L3
TISP4220L3
TISP4240L3
TISP4260L3
TISP4290L3
AJR
AJR
AJR
AJR
AJR
AJR
AJR
AJR
AJR
AJR
AJR
58
65
70
100
120
135
145
160
180
200
230
70
80
90
125
145
165
180
220
240
260
290
150
150
150
150
150
150
150
150
150
150
150
125
125
125
125
125
125
125
125
125
125
125
30
30
30
30
30
30
30
30
30
30
30
40
40
40
40
40
40
40
40
40
40
40
50
50
50
50
50
50
50
50
50
50
50
TISP4xxxLx Series (30 A 10/1000 µs, 50 & 150 mA IH) - Single Bidirectional Overvoltage Protectors (Continued)
IPPSM Ratings for Lightning Surge Standards
Device
TISP4320L3
TISP4350L3
TISP4360L3
TISP4395L3
TISP4070L3
TISP4350L3
Delivery
Options
AJR
AJR
AJR
AJR
BJR
BJR
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
Holding
Current
IH
mA
240
275
290
320
58
275
320
350
360
395
70
350
150
150
150
150
150
150
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
125
125
125
125
TIA/EIA-IS-968
(FCC PART 68)
10/560 µs
A
ITU-T K.20/45/21
5/310 µs
A
40
40
40
40
30
30
50
50
50
50
40
40
30
30
30
30
TISP4xxxMx Series (50 A 10/1000 µs, 150 mA IH) - Single Bidirectional Overvoltage Protectors
IPPSM Ratings for Lightning Surge Standards
Delivery
Options
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
TISP4070M3
TISP4080M3
TISP4095M3
TISP4115M3
TISP4125M3
TISP4145M3
TISP4165M3
TISP4180M3
TISP4200M3
TISP4219M3
TISP4220M3
TISP4240M3
TISP4250M3
TISP4260M3
TISP4265M3
TISP4290M3
TISP4300M3
TISP4350M3
TISP4360M3
TISP4395M3
TISP4400M3
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR
BJR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
AJR, BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
58
65
75
90
100
120
135
145
155
180
160
180
190
200
200
220
230
275
290
320
300
70
80
95
115
125
145
165
180
200
219
220
240
250
260
265
290
300
350
360
395
400
300
300
300
300
300
300
300
300
300
300
300
300
300
300
300
300
300
300
300
300
300
TISP4350MM
TISP4350MM
TISP4360MM
AJR, BJR
AJR, BJR
AJR, BJR
230
275
290
300
350
360
250
250
250
Device
TIA/EIA-IS-968
(FCC PART 68)
10/560 µs
A
ITU-T K.20/45/21
5/310 µs
A
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
50
75
75
75
75
75
75
75
75
75
75
75
75
75
75
75
75
75
75
75
75
75
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
50
50
50
55
55
55
65
65
65
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
TISP4xxxTx Series (80 A 10/1000 µs, 150 mA IH) - Single Bidirectional Overvoltage Protectors
IPPSM Ratings for Lightning Surge Standards
Device
TISP4290T3
TISP4350T3
Delivery
Options
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
BJR
BJR
220
275
290
350
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
250
250
80
80
TIA/EIA-IS-968
(FCC PART 68)
10/560 µs
A
ITU-T K.20/45/21
5/310 µs
A
100
100
120
120
37
TISP4xxxHx Series (100 A 10/1000 µs, 150 & 225 mA IH) - Single Bidirectional Overvoltage Protectors
IPPSM Ratings for Lightning Surge Standards
Delivery
Options
Device
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
Holding
Current
IH
mA
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
TIA/EIA-IS-968
(FCC PART 68)
10/560 µs
A
ITU-T K.20/45/21
5/310 µs
A
TISP4015H1
TISP4030H1
TISP4040H1
BJR
BJR
BJR
8
15
25
15
30
40
50
50
50
500
500
500
100
100
100
125
125
125
150
150
150
TISP4070H3
TISP4080H3
TISP4095H3
TISP4115H3
TISP4125H3
TISP4145H3
TISP4165H3
TISP4180H3
TISP4200H3
TISP4219H3
TISP4220H3
TISP4240H3
TISP4250H3
TISP4260H3
TISP4265H3
TISP4290H3
TISP4300H3
TISP4350H3
TISP4360H3
TISP4395H3
TISP4400H3
TISP4500H3
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR
BJR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
LM, LMR, LMFR
BJR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR
BJR, LM, LMR, LMFR
BJR, LM, LMR, LMFR
BJR
58
65
75
90
100
120
135
145
155
180
160
180
190
200
200
220
230
275
290
320
300
350
70
80
95
115
125
145
165
180
200
219
220
240
250
260
265
290
300
350
360
395
400
500
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
150
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
-
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
-
160
160
160
160
160
160
160
160
160
160
160
160
160
160
160
160
160
160
160
160
160
-
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
TISP4165H4
TISP4180H4
TISP4200H4
TISP4265H4
TISP4300H4
TISP4350H4
BJR
BJR
BJR
BJR
BJR
BJR
135
145
155
200
230
270
165
180
200
265
300
350
225
225
225
225
225
225
500
500
500
500
500
500
100
100
100
100
100
100
160
160
160
160
160
160
200
200
200
200
200
200
TISP4xxxJx Series (200 A 10/1000 µs, 20 mA IH) - Single Bidirectional Overvoltage Protectors
IPPSM Ratings for Lightning Surge Standards
Device
TISP4070J1
TISP4080J1
TISP4095J1
TISP4115J1
TISP4125J1
TISP4145J1
TISP4165J1
TISP4180J1
TISP4200J1
TISP4219J1
TISP4250J1
TISP4290J1
TISP4350J1
TISP4395J1
38
Delivery
Options
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
BJR
58
65
75
90
100
120
135
145
155
180
190
220
275
320
70
80
95
115
125
145
165
180
200
219
250
290
350
395
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
200
200
200
200
200
200
200
200
200
200
200
200
200
200
TIA/EIA-IS-968
(FCC PART 68)
10/560 µs
A
ITU-T K.20/45/21
5/310 µs
A
300
300
300
300
300
300
300
300
300
300
300
300
300
300
350
350
350
350
350
350
350
350
350
350
350
350
350
350
TISP5xxx Series - Single Unidirectional Overvoltage Protectors
IPPSM Ratings for Lightning Surge Standards
Device
TISP5070H3
TISP5080H3
TISP5095H3
TISP5110H3
TISP5115H3
TISP5150H3
Delivery
Options
BJR
BJR
BJR
BJR
BJR
BJR
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
-58
-65
-75
-80
-90
-120
-70
-80
-95
-110
-115
-150
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
500
500
500
500
500
500
100
100
100
100
100
100
TIA/EIA-IS-968
(FCC PART 68)
10/160 µs
A
ITU-T K.20/45/21
5/310 µs
A
250
250
160
250
250
250
200
200
200
200
200
200
TISP7xxx Series - Triple Element Bidirectional Overvoltage Protectors
Device
TISP7015
TISP7038
TISP7072F3
TISP7082F3
TISP7125F3
TISP7150F3
TISP7180F3
TISP7240F3
TISP7260F3
TISP7290F3
TISP7320F3
TISP7350F3
TISP7380F3
TISP7070H3
TISP7080H3
TISP7095H3
TISP7125H3
TISP7135H3
TISP7145H3
TISP7165H3
TISP7180H3
TISP7200H3
TISP7210H3
TISP7220H3
TISP7250H3
TISP7290H3
TISP7350H3
TISP7400H3
Delivery
Options
DR
DR
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
DR, P, SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
SL
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
8
28
58
66
100
120
145
180
200
220
240
275
270
58
65
75
100
110
120
130
145
150
160
160
200
230
275
300
15
38
72
82
125
150
180
240
260
290
320
350
380
70
80
95
125
135
145
165
180
200
210
210
250
290
350
400
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
ANSI C62.41
ITU-T K.20/45/21
2/10 µs
10/1000 µs
8/20 µs
5/310 µs
A
A
A
A
85
85
190
190
190
190
190
190
190
190
190
500
500
500
500
500
500
500
500
500
500
500
500
500
500
500
30
30
45
45
45
45
45
45
45
45
45
45
45
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
150
150
80
80
175
175
175
175
175
175
175
175
175
350
350
350
350
350
350
350
350
350
350
350
350
350
350
350
40
40
70
70
70
70
70
70
70
70
70
70
70
200
200
200
200
200
200
200
200
200
200
200
200
200
200
200
39
TISP6xxx Series - Dual Programmable Overvoltage Protectors
Device
TISP61060
TISP61089
TISP61089S
TISP61089A
TISP61089AS
TISP61089B
TISP61511
TISP61512
TISP61521
TISPPBL1
TISPPBL2
TISPPBL2S
TISPPBL3
Delivery
Options
DR, P
DR, P
DR
DR, P
DR
DR
DR
P
DR
DR, P, SE
DR, P
DR
DR
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
Programmable -5 to -85
Programmable 0 to -85
Programmable 0 to -85
Programmable 0 to -120
Programmable 0 to -120
Programmable 0 to -170
Programmable 0 to -85
Programmable 0 to -85
Programmable 0 to -170
Programmable 0 to -90
Programmable 0 to -90
Programmable 0 to -90
Programmable 0 to -170
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
ANSI C62.41
ITU-T K.20/45/21
2/10 µs
10/1000 µs
8/20 µs
5/310 µs
A
A
A
A
50
120
120
120
120
120
170
170
170
100
100
100
100
30
30
30
30
30
30
30
30
30
30
30
30
30
90
90
100
-
40
40
40
40
40
40
40
40
40
40
40
40
TISP6NTP2x Series - Dual Programmable Overvoltage Protectors
Device
TISP6NTP2A
TISP6NTP2B
Delivery
Options
DR
DR
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
Programmable 0 to -90
Programmable 0 to -120
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
ANSI C62.41
ITU-T K.20/45/21
2/10 µs
10/1000 µs
8/20 µs
5/310 µs
A
A
A
A
85
70
20
20
60
60
25
25
TISP8250 - Programmable Unidirectional Overvoltage Protectors
Device
IPPSM Ratings for Lightning Surge Standards
Delivery
Options
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
2/10 µs
A
10/1000 µs
A
ITU-T K.20/45/21
5/310 µs
A
DR
250
340
75
30
40
TISP8250
GR-1089-CORE
TISP820xM Series - Dual Unidirectional Reverse Blocking Programmable Overvoltage Protectors
Device
TISP8200M
TISP8201M
Delivery
Options
DR
DR
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
Programmable 0 to -90
Programmable 0 to +90
Holding
Current
IH
mA
-150
+20
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
2/10 µs
10/1000 µs
A
A
-45
+45
ITU-T K.20/45/21
5/310 µs
A
-210
+210
-70
+70
TISP83121 Series - Dual-Gate Unidirectional Overvoltage Protectors
Device
TISP83121
40
Delivery
Options
DR
Standoff
Voltage
VDRM
V
Protection
Voltage
V(BO)
V
Programmable 0 to ±100
IPPSM Ratings for Lightning Surge Standards
GR-1089-CORE
10/1000 µs
A
ANSI C62.41
8/20 µs
A
ITU-T K.20/45/21
5/310 µs
A
150
500
150
Surge
Line Protection Modules
Selection Guide
Features
Custom Designs
• Precision thick-film technology
• Withstands lightning and AC power cross
• Complies with Telcordia (Bellcore) GR-1089
requirements
• Complies with ITU-T K.20 requirements
• Surface mount solution
• Guaranteed to fail safely under fault conditions
• Optional one-shot thermal fuse
• Optional resettable PTC
• UL 497A recognized
• Non-flammable
• Standard offerings
• Custom designs
• Full qualification test capabilities
• Central Office, Remote and Customer Premise
Equipment applications include:
- Analog linecards - xDSL linecards
- Pairgain
- VoIP
- PBX systems
- External and
- LCAS protection
intra-buildings
In addition to the various standard off-the-shelf
versions available, Bourns offers extensive custom
options. Examples include:
• Variety of packages, e.g. vertical and horizontal SMD
• Packaging options, e.g. trays, tape and reel, bulk
• Additional resistors, e.g. ringing power resistors
• Additional components, e.g. fuses, PTCs,
overvoltage protection
• Resistors from 5.6 Ω
• Ratio matching: down to 0.3 %, or less with
special limitations
Model
Schematic
Dimensions
Description
51.05
MAX.
(2.010)
F1
R1
R2
MAX.
F2
11.30
(.445)
4B08B-511-500
3
5
7
8
12
13
15
17
2.03
(.080)
MAX.
3.43 ± .38
(.135 ± .015)
7.62
(.300)
3
5
7 8
10.16
(.400)
5.08
(.200)
12
13
15
17
.51
(.020)
2.54
(.100)
25.40 ± 0.50
(1.000 ± .020)
Functional Schematic*
0.36
(.014)
2.03
(.080)
MAX.
11.30 ± 0.50
(.450 ± .020)
4B04B-502-RC
1
2
*User must short pins 9 & 10 on the circuit board.
1
2.54 ± .127
(.100 ± .005)
4B06B-512-RC
2
9
10
17.78 ± .254
(.700 ± .010)
2.54 ± .127
(.100 ± .005)
33.27
MAX.
(1.310)
R1
1
2
3
11 12 13
F1
1.27
(.050)
F2
1 2 3
R2
1.27
(.050)
11 12 13
20.32
(.800)
0.36
(.014)
MAX.
3.18
(.125)
MAX.
11.43
MAX.
(.450)
• 2x 50 Ω, 1%
• 0.5 % matching
• Thermal fuses
2.54
(.100)
2.29
(.090)
MAX.
0.36
(.014)
MAX.
• 1x R Ω, 5 %
• Values 5.6-100 Ω
• Thermal fuse
•
•
•
•
2x R Ω, 5 %
Values 5.6-100 Ω
0.5 % matching
Thermal fuses
41
Model
Schematic
Dimensions
5.10 ± .13
(0.200 ± .005)
4A08P-505-RC
2
3
1
4
2.54 ± .13
(0.100 ± .005)
22.35 ± .13
(0.880 ± .005)
2
3
1
4
0.51 ± .05
(0.020 ± .002)
1.02 ± .05
(0.040 ± .002)
22.35 ± .05
(0.880 ± .002)
RADIUS
.38
(.015)
MAX.
2.54 ± .13
(0.100 ± .005)
12.70 ± .13
(0.500 ± .005)
4.10 ± .25
(0.160 ± .010)
22.50 ± .38
(0.885 ± .015)
1.270 ± .127 1.270 ± .127
(0.050 ± .005) (0.050 ± .005)
0.25 ± .05
(0.010 ± .002)
2.80
(.110)
12.70
(.500)
14.59
(.575)
R1B
F2B
F1B
22
21
19
15
13
12
1
2
4
8
10
11
F1A
4A12P-516-500
DCODE
1 2
4
3.72
(.146)
10.16 ± .13
(.400 ± .005)
5.08 ± .13
(.200 ± .005)
F2A
R1A
R2A
8
2.54 ± .13
(.100 ± .005)
4.07 ± .25
(.160 ± .010)
4B06B-514-500
1
12.32
(.485)
MAX.
R4
2
4
6
8
2
4
5.08
(.200)
3 PLCS.
11
3
1,8
8
9
0.36
(.014)
MAX.
2.54
(.100)
2 PLCS.
13
14
APPROXIMATE
TISP® LOCATION
4.57
(.180)
MAX.
35.56
MAX.
(1.400)
MAX.
12.70
(.500)
4B07B-530-400
DCODE
3.43 ± .38
(.135 ± .015)
1.27
2 PLCS.
(.050)
R2
1 2 3
11 12 13 14
5 PLCS.
2.54
(.100)
20.32
(.800)
1
2
11
3
F1
13
F2
R2
42
12
• 2x 40 Ω, 2 %
• 0.5 % matching
• Integrated
overvoltage
TISP®
MAX.
0.36
(.014)
APPROXIMATE
FUSE LOCATIONS
TISP V(B01) TISP V(B02)
APPROXIMATE
TISP® LOCATION
4.57
(.180)
MAX.
33.02
MAX.
(1.300)
4B06B-540-125/219
MAX.
1.91
(.075)
F2
R1
• 2x 50 Ω, 1 %
• 1.0 % matching
• Resettable
Multifuse® PPTC
APPROXIMATE
FUSE LOCATIONS
2
12
6
3.43 ± .38
(.135 ± .015)
61089B
F1
2
2.54
(.100)
2 PLCS.
4,5
6,7
1
4B06B-514-500
DCODE
1
9
R1
4B07B-530-400
4.32
(.170)
MAX.
R2
R3
• 4x 50 Ω, 1 %
• 0.5 % matching
• Thermal fuses
10 11
25.65
MAX.
(1.010)
R1
• 2x R Ω, 5 %
• Values 5.6-100 Ω
• 1 % matching
MAX.
7.87
(.310)
32.81
MAX.
(1.292)
R2B
4A12P-516-500
Description
MAX.
11.43
(.450)
3.43 ± .38
(.135 ± .015)
1.27
2 PLCS.
(.050)
TISP
4B06B-540-V(B01) /V(B02)
DCODE
1 2 3
TISP
11 12 13
20.32
(.800)
4 PLCS.
2.54
(.100)
MAX.
1.91
(.075)
0.97
(.038)
0.36
MAX.
(.014)
• 2x 10 Ω, 5 %
• 2.0 % matching
• Integrated
overvoltage
TISP®
Telefuse™
Telecom Fuses
Selection Guide
Features
• Model 1250T is designed for use in telecommunications circuit applications requiring low current
protection with high surge tolerance
• Ideal for protecting Central Office and Customer
Premise Equipment, including POTS, T1/E1, ISDN
and xDSL circuits
Model
Device Symbol
B1250T
B0500T
0.5
0
• Model B1250T allows overcurrent compliance
with telecom specifications including Telcordia
GR-1089, UL 60950, and ITU K.20 and K.21
• Model B0500T is a lower current version for use in
applications where a faster opening time may be
required
Ampere
Rating
A
Voltage
Rating
V
Peak Surge
Current
10/1000 A
1.25
600
100
0.5
600
25
43
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Country
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Fax
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Phone
Fax
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+886-2-25624117
+41- 41-7685555
+1-909-781-5500
+886-2-25624116
+41- 41-7685510
+1-909-781-5700
Technical Assistance
www.bourns.com
www.bournscircuitprotection.com
Bourns® products are available through an extensive network of manufacturer’s representatives, agents and distributors.
To obtain technical applications assistance, a quotation, or to place an order, contact a Bourns representative in your area.
Circuit Protection Solutions
“Telefuse” and “MINI TRIGARD” are trademarks of Bourns, Inc.
“TISP” is a trademark of Bourns, Ltd., and is Registered in U.S. Patent and Trademark Office.
“Multifuse and MSP” are registered trademarks of Bourns, Inc.
“Bourns” is a registered trademark of Bourns, Inc. in the U.S. and other countries.
COPYRIGHT© 2002, BOURNS, INC. LITHO IN U.S.A. DP 11/02 15M/K0115