Rapid testing automotive and stationary batteries
(BU42
Portable
batteries for cell phones, laptops and cameras may be rapid-tested by applying
a number of load pulses while observing the relationship between voltage and current.
Ohm's Law is used to calculate the internal resistance. Comparing the readings
against a table of values estimates the battery's state-of-health.
This
load pulse method does not work well for larger batteries and AC conductance is
commonly used. An AC voltage is applied to the battery terminals that floats as
a ripple on top of the battery's DC voltage and charges and discharges the battery
alternatively.
AC conductance has been incorporated into a number of
hand-held testers to check batteries for vehicular and stationary batteries. To
offer simple and low-cost units, these testers load the battery with pulses rather
than injecting sinusoidal signals. The pulses are commonly not voltage controlled
and the thermal battery voltage* may be surpassed. The thermal voltage threshold
of a lead-acid battery is 25mV per cell. Exceeding this voltage is similar to
over-driving an audio amplifier. Amplified noise and distortion is the result.
AC conductance provides accurate readings, provided the battery is fully
charged, has rested or has been briefly discharged prior to taking the reading.
AC conductance tends to become unreliable on low charge and sometimes fails a
good battery. At other times, a faulty battery may pass as good. The correlation
to the battery's state-of-charge is a common complaint by users. AC conductance
works best in identifying batteries with definite deficiencies.
AC conductance
is non-invasive, quick and the test instruments are relatively inexpensive. There
are, however, some fundamental problems. Most commercial testers use only one
frequency, which is commonly below 100 Hertz. Multi-frequency systems would be
more accurate but require complex data interpretation software and expensive hardware.
In this paper we focus on Electrochemical Impedance Spectroscopy (EIS), a method
that overcomes some of the shortcomings of AC conductance.
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* Batteries are non-linear systems. The equations, which govern
the battery's response becomes linear below 25mV/cell at 25°C. This voltage
is called the battery thermal voltage.
Electrochemical
Impedance Spectroscopy (EIS)
EIS evaluates the electrochemical characteristics
of a battery by applying an AC potential at varying frequencies and measuring
the current response of the electrochemical cell. The frequency may vary from
about 100 micro Hertz (µHz) to 100 kilo Hertz (kHz). 100µHz is a very
low frequency that takes more than two hours to complete one full cycle. In comparison,
100kHz completes 100,000 cycles in one second.
Applying various frequencies
can be envisioned as going through different layers of the battery and examining
its characteristics at all levels. Similar to tuning the dial on a broadcast radio,
in which individual stations offer various types of music, so also does the battery
provide different information at varying frequencies.
Battery resistance
consists of three types, which are: pure resistance, inductance and capacitance.
Figure 1 illustrates the classic Randles model,which represents a typical battery
|
| Figure
1: Randles model of a lead acid battery. The overall battery resistance consists
of pure Ohmic resistance, inductance and capacitance. There are many other models |
Capacitance
is responsible for the capacitor effect; and the inductance is accountable for
the so-called magnetic field, or coil effect. The voltage on a capacitor lags
behind the current. On a magnetic coil, on the other hand, the current lags behind
the voltage. When applying a sine wave to a battery, the reactive resistance produces
a phase shift between voltage and current. This information is used to evaluate
the battery.
EIS has been used for a number of years to perform in-flight
analysis of satellite batteries, as well as estimating grid corrosion and water
loss on aviation and stationary batteries. EIS gives the ability to observe the
kinetic reaction of the electrodes and allows analyzing changes of analyze changes
that occur in everyday battery usage. Increases in impedance readings hint at
minute intrusion of corrosion and other deficiencies. Impedance studies using
the EIS methods have been carried out on lead-acid, nickel-cadmium, nickel-metal-hydride
and lithium-ion batteries. Best results are obtained on a single cell.
One of the difficulties of EIS is data interpretation. It is easy to amass a large
amount of data; making practical use of it is more difficult. Analyzing the information
is further complicated by the fact that the readings are not universal and do
not apply equally to all battery makes and types. Rather, each battery type generates
its own set of signatures. Without well-defined reference readings and software
to interpret the results, gathering information has little meaning for the ordinary
person.
Modern technology can help by storing characteristic settings
of a given battery type in the test instrument. Advanced digital signal processors
are able to carry out millions of instructions per second. Software translates
the data into a single reading. EIS has the potential of becoming a viable alternative
to AC conductance in checking automotive, traction and stationary batteries. Noteworthy
advancements are being made in his field.
Commercializing
Electrochemical Impedance Spectroscopy
Cadex is developing a battery rapid test method incorporating EIS based techniques.
Trademarked Spectro™, the system injects sinusoidal signals at multiple frequencies.
The signals are voltage controlled and remain below the thermal battery voltage.
Spectro™ is being tested on randomly sampled automotive batteries
of various states-of-health conditions. Automotive batteries serve the purpose
well because of easy availability. To demonstrate the accuracy, we tested six
typical automotive batteries (A, B, C, D, E, and F) with various state-of-health
conditions. The batteries are flooded lead acid of the same model.
Prior
to testing, the batteries were fully charged and the actual Cold Cranking Ampere
(CCA) reading was established using standards developed under SAE J537. The batteries
were then re-tested using the AC conductance and Spectro™ methods. The Spectro™
approximations were conducted using model-specific matrices.
| |
Figure
2: Comparison readings of CCA and Spectro™ using battery-specific matrices.
The blue markers compare readings with AC conductance. Spectro™ follows the
CCA measurements very closely. |
Batteries
arrive for testing in all conditions, including low state-of-charge (SoC). With
AC conductance, the charge level affects the CCA readings to such a degree that
the test results may become meaningless. To demonstrate SoC immunity of Spectro™,
Spectro was used to estimate CCA at different charge levels. The results are shown
in Figure 3.
 | Figure
3: CCA rapid-tests at various SoC. Spectro™ provides robust readings
from 40-100% SoC. The
AC conductance readings are strongly affected by the charge level. |
Ideally,
the line should be perfectly horizontal. Spectro™ departs only moderately
within the 40-100% SoC range. In comparison, the CCA approximations using AC conductance
show a strong departure from the horizontal line, caused by the charge level.
Although early test results conducted with the Spectro™ based technology
demonstrate strong advantages over existing test methods, the electrical requirements
and complexities are demanding. Injecting multi-frequency sinusoidal signals at
controlled levels and processing reams of data will add cost.
Research is continuing to include a broad range of battery sizes
and chemistries, and to reduce the test time from two minutes
to about 20 seconds per battery test. Patents for Spectro™
have been applied for.
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Created: March 2003, Last edited: January 2006
