Industry Outlook
Changing Focus of Battery Chargers for Differing Battery Chemistries
Bob Wylie, Director
Advanced Charger Technology
Since its incorporation in the late 1990s,
Advanced Charger Technology (ACT) has
maintained its focus on the charging and
maintenance of rechargeable batteries used
on portable two-way radios and thermal
imaging devices. Throughout this time there
has been a trade-off at the user level in terms
of overall weight considerations, battery costs and energy demands of the battery from enhancements in radio features. The
evolution of battery chemistry technology, each with its own
unique set of charging requirements, has represented the biggest
challenge to our market goals.
In the mid to late 1990s, Nickel Cadmium (NiCD) was
the primary battery chemistry used in portable two-way radio
devices. The cadmium in the battery was soon widely criticized
for its negative impact on the environment, yet NiCD batteries
were found to be very robust, had long shelf lives and were quite
safe to use. The other major criticism of NiCD batteries was that
they were relatively heavy for most portable radio users, which
served to limit the overall battery capacity. In addition, NiCD
was very susceptible to increased dendrite formation and lost
battery capacity resulting from "topping off" of the battery.
In the early 2000s, nickel metal hydride (NiMH) battery
chemistries rose in popularity to compliment and in many cases
replace the NiCD batteries on two-way radios. NiMH was positioned as not suffering the same environment concerns as NiCD;
however, it is generally not considered as robust a chemistry.
NiMH does not release current as effectively as NiCD, which is
especially noticeable under cold weather conditions, but it does
offer the ability for increased battery capacities without adding
appreciable weight, relative to NiCD. While NiMH also can
suffer from dendrite formation and lost battery capacity it is not
as susceptible as NiCD. Although NiM did not replace NiCD
completely, it took a large part of the market primarily because
it was lighter and therefore was generally of higher capacity. It
was more expensive and had a shorter life cycle than NiCD.
While Lithium chemistry batteries have been available for
some time, it was not until the mid 2000s when this chemistry
gained wide stream acceptance from end users.
Compared to nickel-based batteries, lithium-based batteries have a higher energy density making them more compact
and lighter. Lithium also offers a higher cell voltage and lower
self-discharge. However, lithium is very volatile and needs to
be very carefully charged and maintained. The run-time due to
the low weight and therefore high capacity is longer as compared to nickel-based batteries but the overall battery cycle life
is not as good. Also, the most common concern with lithium is
the ever-present danger of thermal runaway or fire risk as has
been publicized on a number of occasions with laptop batteries.
Over-charging is a very real danger of damaging lithium battery
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cells. While not the explosive event that has lead to recalls of
some laptop and car batteries, this damage results in permanent
and irreparable harm to battery cells. This is not recent news, as
was published back in 2008, "Permanent capacity loss, as the
name implies, refers to permanent loss that is not recoverable by
charging. Permanent capacity loss is mainly due to the number
of full charge/discharge cycles, battery voltage and temperature.
The more time the battery remains at 100 percent charge, the
faster the capacity loss occurs."1 ACT has developed a means to
control the termination levels in order to maximize the battery
life cycle.
In 2011, Advanced Charger Technology, Inc. launched its
new generation of charging technology. These new generation
chargers focused on charging termination sequences for both
nickel-based and lithium-based cell batteries as well as its charging algorithms for the different battery chemistries. This resulted
in chargers capable of charging nickel- and lithium-based chemistry batteries to the batteries maximum safe capacity without
the danger of thermal runaway and without the generation of
heat to compromise the battery.
The revised charging termination sequence will ensure that
there is no overcharge and overheating of the battery thereby
extending the life cycle of the battery.
As newer battery chemistry technologies gain wider acceptance, such as the growth of lithium polymer, ACT is committed
to meeting the unique demands these batteries while still mindful of other battery chemistries still in use.
Reference
1 Power Electronics Technology, April 2008. "Proper Care
Extends Li-Ion Battery Life" by Fran Hoffart
For more information please visit www.actcharge.com.
Summer 2014 * Battery Power
7
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Table of Contents for the Digital Edition of Battery Power - Summer 2014