UL248-1 1608 Fast Acting Surface Mount Fuse 06D 250mA-5A 32V With
Interrupting Rating 35A 50A
Description
1608 fast-acting Surface mount fuse are in small size can save
space of PCB,suitable for lots of electronics board. , fuse is made
of thin film, with low resistance, stable electrical properties and
high reliability, and is adaptable to reflow and wave soldering,
fuse has fast response and is suitable for the circuit without
instantaneous current surge, fuse is mainly used in current
protection, IC protection, mobile phone and other communication
devices, display, digital camera, battery.
Dimension in mm
Specifications
| Catalog | Ampere | Voltage |
Marking | Melting Integral |
| No. | Rating | Rating | (A2.S) |
| 06D0250D | 250mA | 32V | D | 0.00040 |
| 06D0375D | 375mA | 32V | E | 0.00087 |
| 06D0500D | 500mA | 32V | F | 0.00188 |
| 06D0750D | 750mA | 32V | G | 0.00880 |
| 06D1100D | 1A | 32V | H | 0.00250 |
| 06D1125D | 1.25A | 32V | J | 0.0125 |
| 06D1150D | 1.5A | 32V | K | 0.0310 |
| 06D1200D | 2A | 32V | N | 0.0480 |
| 06D1250D | 2.5A | 32V | O | 0.0615 |
| 06D1300D | 3A | 32V | P | 0.0690 |
| 06D1350D | 3.5A | 32V | R | 0.1181 |
| 06D1400D | 4A | 32V | S | 0.2380 |
| 06D1500D | 5A | 32V | T | 0.6817 |
Time-Current Features
| % of Ampere Rating | Opening Time |
| 100% | 4 hours Min |
| 200% | 60 s Max |
Others
| Blown Type | Fast-acting |
| Standard according to | UL248-1 UL248-14 |
| Interrupting Rating: | 50 Amperes at 32V DC(250mA~1A)
35 Amperes at 32V DC(1.25A~5A) |
| Operating Temperature | -55℃ ~+125℃ |
| Materials | Substrate:ceramic/glass cover
Termination:sliver over-plated with nickel and tin
Element:silver |
| Soldering method | Reflow soldering: 260℃, 10s max |
| Packaging | Automaton taped 5000PCS per rell,
150000PCS per carton |
| MOQ | 5000PCS |
| Lead time | 2 weeks |
| Agency | UL |
Application
White goods, power supply, industrial
control,automotive,UPS,battery etc.
Features
Single blow fuse for overcurrent protection
1608 (EIA 0603) miniature footprint
Fast blow fuse
UL 248-14 listed
Surface mount packaging for automated assembly
Multilayer SMD design
RoHS compliant* and halogen free
Time-Current Characteristics Curve
Main Export Markets
Central/South America
Eastern Europe
Mid East/Africa
North America
Western Europe
Asia
Australasia
Selecting the right fuse
Choosing the right fuse can thwart equipment damage, prevent costly
maintenance, and protect the user
The role of circuit protection devices has traditionally been
labeled as perhaps the least important aspect of a design: an
afterthought and an oftentimes irritating detail. Today, the
sophistication of circuit design and the appropriate selection of a
protective device require careful thought in the early stages and
throughout.
It requires a competence, knowledge of varying types of devices, an
understanding of the different functions they provide, and the
ability to determine the most suitable device for an application.
Choosing the right fuse ensures ongoing equipment function and
prevents expensive maintenance due to nuisance blows. It protects
the equipment altogether and, more important, the safety of the
user.
Selecting the right fuse requires careful thought in the early
stages of&sh;as well as throughout&sh;the design.
Circuit operating conditions
In order to begin selecting the appropriate fuse, one needs to
understand the nature of the circuit it powers and protects. Basic
operating factors such as the maximum steady-state voltage, current
values, and ambient temperature have to be defined. Additionally,
it is necessary to understand the peak value and duration/shape of
surge currents that may exist.
Rated current and ambient temperature
Like most electrical components, fuses must be derated over
temperature. At 60C, for example, a circuit that would use a 1-A
time-delay fuse at room temperature will need a 1.25-A fuse to
support operation at the higher temperature (see Fig. 1).
Fig. 1. The derating curve shown is a general curve for medium
time-lag (T) and quick-acting (F). Refer to manufacturers product
specific curves for each type of fuse.It is important to remember
that the fuse has a resistance, and therefore will incur voltage
drop and dissipate power. Time-lag fuses normally have lower
voltage drops and power dissipation values than equally rated
quick-acting fuses.
For example, a time-lag 2-A 5 x 20-mm fuse has a typical voltage
drop of 60 mV, whereas the quick-acting version has a voltage drop
of 90 mV. The reason for this is due to time-lag fuses having a
thicker fuse wire diameter, which results in a higher I²t value or
energy required to melt the fuse wire. Additionally, the fuse wire
is tin-plated. This means that during normal operation,
quick-acting fuses heat up to a higher temperature level before
interrupting.
Fuse location
The location of the fuse in a circuit is also important to prevent
unnecessary heat accumulation. The type and proximity of other
components near and around the fuse affects ambient temperature.
Higher temperatures can effect the manufacturer’s specified time
vs. current characteristics. Understand that measures taken to
directly deflect heat away from the fuse&sh;enlarged solder
pads, cooling sinks, fans&sh;are likely to change the stated
performance characteristics.
Breaking capacity
Breaking Capacity is the maximum fault current in which the fuse
can safely interrupt. Fuses used in situations where fault currents
exceed the breaking capacity can catch fire or even explode in
extreme cases.
For example, a fuse with a breaking capacity of 35 A should never
be used when the power source exceeds 35 A worst case, but will
offer adequate protection where fault currents do not exceed 35 A.
Safety agencies determine acceptable breaking capacity limits
according to predefined factors.
As a rule of thumb, a high-breaking-capacity fuse is recommended
for circuits with inductive load, a p.f. of less than 0.9. A
low-breaking-capacity fuse is usually sufficient for circuits with
resistive/capacitive loads.
The actual power factor of the equipment can affect the
manufacturer’s specified ratings. Some manufacturers provide
additional breaking capacity ratings at varying power factors to
further assist customers in determining suitability of a product.
Time-current characteristics
Some applications have specific and easily understood needs when it
comes to the speed at which the fuse should blow. Sensitive
semiconductor circuits oftentimes need fast-acting fuses that blow
within very short periods of time, while equipment taking large
inrush currents may need a time-lag fuse to prevent nuisance
outages.
In cases where either type could be used, it is helpful to refer
back to the effect of ambient temperature in making the selection
and remember that time-lag fuses typically have a lower voltage
drop than fast-acting fuses and therefore dissipate less power.
Pre-arcing times at moderate overcurrents (1 < 2.5*In) are
almost the same (see Fig. 2). At greater overcurrents (1 =
10.0*In), time-lag fuses have higher prearcing times than
quick-acting fuses.
Fig. 2. Pre-arcing times for quick-acting and time-lag fuses at
moderate overcurrents are almost the same.
Calculating melting energy
I2t is a measure of the energy required to melt the fuse wire in
the fuse. The approximate length of time it will take for a fuse to
blow can be determined by dividing the I2t value specified by the
manufacturer by the square of the expected fault current.
For example, for a fuse with I2t = 4.5 A2s the expected fault
current is 13 A:
ttyp = I2t/I2 = 4.5 A2s/(1.25 A * 10)2 = 28.8ms
Conversely, knowing the expected fault current value and having in
mind a specific time one wants a fuse to blow in, it can be
determined what I2t value is needed for a specific requirement.
Once the required I2t has been determined, it is relatively easy to
check a candidate fuses’ specification to find the fuse that meets
one’s needs.
Available product types
The IEC standards cover miniature fuses for equipment in a large
number of different sizes and package types, ranging from 5x20-mm
cartridge types to 1206 SMD. Terminal variations include pig-tails,
through-hole, and SMD, and are offered in bulk or tape and reel,
typically the case for chip fuses.
There are some unique differences between the IEC standards versus
the UL standards, and compliance with one or the other or both must
be considered when looking at domestic and export markets. It is
not necessarily possible to substitute a UL fuse with an IEC or
vice-versa, although one might think that one 1-A fuse is just like
another. Time-current characteristics are different, and where a UL
fuse may blow in a matter of hours when operated at 1 A, a fuse
designed to IEC should not blow at all at 1 A, and may suggest that
a 2-A fuse is needed.
Making the final selection
Once the rated voltage and currents, breaking capacity, and
time-current characteristics are determined together with the
current I2t, and the desired package styles are known, it is
possible to check candidate types for a fit. If the fuse is to be
mounted in a fuseholder, it is especially important to observe
power dissipation limits of the both the fuseholder and the fuse.
The appropriate fuseholder
Fuses are often mounted in holders to facilitate ease of
replacement. The fuseholder will have additional important
electrical characteristics: contact resistance and maximum
allowable fuse power dissipation.
One must also keep in mind that the holder, like the fuse, must
also be derated at higher temperatures. Fuseholders are available
in many styles for panel mounting in equipment where fuses need to
be user replaceable, and as clips or blocks that can be mounted to
the chassis or PCB inside the equipment.
Both types can be found with quick-connect terminals or PCB
terminals, and PCB types are available for through-hole or SMD
connections. PCB holder types are available for vertical or
horizontal mounting to allow flexibility in chassis design. Some
types are even available with fuses already installed for faster
assembly and lower installed cost.
