General Battery Information
With today's trend towards portable electronic solutions
as well as mankind's need for power, the need for batteries
is ever increasing. Today, consumer batteries are classified
under two categories: Primary and Secondary.
PRIMARY BATTERIES (NON-RECHARGEABLE)
A primary battery is a battery that is designed to
be cycled (fully discharged) only once and then discarded.
Although primary batteries are often made from the same
base materials as secondary (rechargeable) batteries,
the design and manufacturing processes are not the same.
Primary batteries or what some refer to as non-rechargeable
batteries. This type of battery includes your common
alkaline, silver oxide, zinc, and lithium. These batteries
are used in low drain applications such as cameras,
remote controls, flashlights, calculators, hearing aids
etc. A wide variety of manufacturers make primary batteries.
These include Energizer, Duracell, Panasonic, GP, Kodak
etc.
Battery manufacturers recommend that primary batteries
not be recharged. Although attempts at recharging a
primary battery will occasionally succeed (usually with
a diminished capacity), it is more likely that the battery
will simply fail to hold any charge, will leak electrolyte
onto the battery charger, or will overheat and cause
a fire. It is unwise and dangerous to recharge a primary
battery
SECONDARY BATTERIES (RECHARGEABLE BATTERIES)
Secondary batteries are also known as rechargeable
batteries. These are increasing in popularity as portable
products are everywhere. The quality of batteries and
the types available now have improved vastly in the
last ten years. The following information is taken from
a book called "Batteries in a Portable World"
written by Isidor Buchmann. This wonderful book can
be purchased at http://www.buchmann.ca/default.asp
Let's examine the advantages and limitations of today's
popular battery systems. Batteries are scrutinized not
only in terms of energy density but service life, load
characteristics, maintenance requirements, self-discharge
and operational costs. Since NiCd remains a standard
against which other batteries are compared, let's evaluate
alternative chemistries against this classic battery
type.
Nickel Cadmium (NiCd) - mature and well understood
but relatively low in energy density. The NiCd is used
where long life, high discharge rate and economical
price are important. Main applications are two-way radios,
biomedical equipment, professional video cameras and
power tools. The NiCd contains toxic metals and is not
environmentally friendly.
Nickel-Metal Hydride (NiMH) - has a higher energy
density compared to the NiCd at the expense of reduced
cycle life. NiMH contains no toxic metals. Applications
include mobile phones and laptop computers.
Lead Acid - most economical for larger power applications
where weight is of little concern. The lead acid battery
is the preferred choice for hospital equipment, wheelchairs,
emergency lighting and UPS systems.
Lithium Ion (Li-ion) - fastest growing battery
system. Li-ion is used where high-energy density and
light weight is of prime importance. The Li-ion is more
expensive than other systems and must follow strict
guidelines to assure safety. Applications include notebook
computers and cellular phones.
Lithium Ion Polymer (Li-ion polymer) - a potentially
lower cost version of the Li-ion. This chemistry is
similar to the Li-ion in terms of energy density. It
enables very slim geometry and allows simplified packaging.
Main applications are mobile phones.
Reusable Alkaline - replaces disposable household
batteries; suitable for low-power applications. Its
limited cycle life is compensated by low self-discharge,
making this battery ideal for portable entertainment
devices and flashlights.
|
|
|
|
NiCd
|
NiMH
|
Lead
Acid
|
Li-ion
|
Li-ion
polymer
|
Reusable
Alkaline
|
|
|
|
Gravimetric Energy Density (Wh/kg)
|
45-80
|
60-120
|
30-50
|
110-160
|
100-130
|
80
(initial)
|
|
Internal
Resistance
(includes peripheral circuits) in mW
|
100
to 2001
6V pack
|
200
to 3001
6V pack
|
<1001
12V pack
|
150
to 2501
7.2V pack
|
200
to 3001
7.2V pack
|
200
to 20001
6V pack
|
|
Cycle
Life
(to 80% of initial capacity)
|
15002
|
300
to 5002,3
|
200
to
3002
|
500
to 10003
|
300
to
500
|
503
(to 50%)
|
|
Fast
Charge Time
|
1h
typical
|
2-4h
|
8-16h
|
2-4h
|
2-4h
|
2-3h
|
|
Overcharge
Tolerance
|
moderate
|
low
|
high
|
very
low
|
low
|
moderate
|
|
Self-discharge
/ Month
(room temperature)
|
20%4
|
30%4
|
5%
|
10%5
|
~10%5
|
0.3%
|
|
Cell
Voltage
(nominal)
|
1.25V6
|
1.25V6
|
2V
|
3.6V
|
3.6V
|
1.5V
|
|
Load Current
-
peak
- best result
|
20C
1C
|
5C
0.5C or lower
|
5C7
0.2C
|
>2C
1C or lower
|
>2C
1C or lower
|
0.5C
0.2C or lower
|
|
Operating
Temperature
(discharge only)
|
-40
to
60°C
|
-20
to
60°C
|
-20
to
60°C
|
-20
to
60°C
|
0
to
60°C
|
0
to
65°C
|
|
Maintenance
Requirement
|
30
to 60 days
|
60
to 90 days
|
3
to 6 months9
|
not
req.
|
not
req.
|
not
req.
|
|
Typical
Battery Cost
(US$, reference only)
|
$50
(7.2V)
|
$60
(7.2V)
|
$25
(6V)
|
$100
(7.2V)
|
$100
(7.2V)
|
$5
(9V)
|
|
Cost
per Cycle
(US$)11
|
$0.04
|
$0.12
|
$0.10
|
$0.14
|
$0.29
|
$0.10-0.50
|
|
Commercial
use since
|
1950
|
1990
|
1970
|
1991
|
1999
|
1992
|
|
|
Figure 2-1: Characteristics of commonly used rechargeable
batteries.
The figures are based on average ratings
of batteries available commercially at the time of publication;
experimental batteries with above average ratings are
not included.
