Electric Vehicles - Batteries
Whether
you are a
proponent of
electric
vehicles or
not, this is
very
interesting
information.
This is an
unusual and
thought
provoking
article by
Bruce
Haedrich.
When I
saw the title
of this
lecture,
especially
with the
picture of the
scantily clad
model, I
couldn’t
resist
attending. The
packed
auditorium was
abuzz with
questions
about the
address;
nobody seemed
to know what
to expect. The
only hint was
a large
aluminum block
sitting on a
sturdy table
on the stage.
When the crowd
settled down,
a
scholarly-looking
man walked out
and put his
hand on the
shiny block,
“Good
evening,” he
said, “I am
here to
introduce
NMC532-X,” and
he patted the
block, “we
call him NM
for short,”
and the man
smiled
proudly. “NM
is a typical
electric
vehicle (EV)
car battery in
every way
except one; we
programmed him
to send
signals of the
internal
movements of
his electrons
when charging,
discharging,
and in several
other
conditions. We
wanted to know
what it feels
like to be a
battery. We
don’t know how
it happened,
but NM began
to talk after
we downloaded
the program.
Despite this
ability, we
put him in a
car for a year
and then asked
him if he’d
like to do
presentations
about
batteries. He
readily agreed
on the
condition he
could say
whatever he
wanted. We
thought that
was fine, and
so, without
further ado,
I’ll turn the
floor over to
NM,” the man
turned and
walked off the
stage.
“Good
evening,” NM
said. He had a
slightly
affected
accent, and
when he spoke,
he lit up in
different
colors. “That
cheeky woman
on the marquee
was my idea,”
he said. “Were
she not there,
along with
‘naked’ in the
title, I’d
likely be
speaking to an
empty
auditorium! I
also had them
add ‘shocking’
because it’s a
favorite word
amongst us
batteries.” He
flashed a
light blue
color as he
laughed.
“Sorry,” NM
giggled then
continued,
“three days
ago, at the
start of my
last lecture,
three people
walked out. I
suppose they
were
disappointed
there would be
no dancing
girls. But
here is what I
noticed about
them. One was
wearing a
battery-powered
hearing aid,
one tapped on
his
battery-powered
cell phone as
he left, and a
third got into
his car, which
would not
start without
a battery. So,
I’d like you
to think about
your day for a
moment; how
many batteries
do you rely
on?”
He paused for
a full minute
which gave us
time to count
our
batteries.
Then he went
on, “Now, it
is not
elementary to
ask, ‘what is
a battery?’ I
think Tesla
said it best
when they
called us
Energy Storage
Systems.
That’s
important. We
do not make
electricity –
we store
electricity
produced
elsewhere,
primarily by
coal, uranium,
natural
gas-powered
plants, or
diesel-fueled
generators.
So, to say an
EV is a
zero-emission
vehicle is not
at all valid.
Also, since
forty percent
of the
electricity
generated in
the U.S. is
from
coal-fired
plants, it
follows that
forty percent
of the EVs on
the road are
coal-powered,
n’est-ce pas?”
He flashed
blue again.
“Einstein’s
formula,
E=MC2, tells
us it takes
the same
amount of
energy to move
a
five-thousand-pound
gasoline-driven automobile a mile as it does an electric one. The only
question again
is what
produces the
power? To
reiterate, it
does not come
from the
battery; the
battery is
only the
storage
device, like a
gas tank in a
car.”
He lit up red
when he said
that, and I
sensed he was
smiling. Then
he continued
in blue and
orange. “Mr.
Elkay
introduced me
as NMC532. If
I were the
battery from
your computer
mouse, Elkay
would
introduce me
as double-A,
if from your
cell phone as
CR2032, and so
on. We
batteries all
have the same
name depending
on our design.
By the way,
the ‘X’ in my
name stands
for
‘experimental.’
There are
two orders of
batteries,
rechargeable,
and single
use. The most
common
single-use
batteries are
A, AA, AAA, C,
D. 9V, and
lantern types.
Those dry-cell
species use
zinc,
manganese,
lithium,
silver oxide,
or zinc and
carbon to
store
electricity
chemically.
Please note
they all
contain toxic,
heavy metals.
Rechargeable
batteries only
differ in
their internal
materials,
usually
lithium-ion,
nickel-metal
oxide, and
nickel-cadmium.
The United
States uses
three billion
of these two
battery types
a year, and
most are not
recycled; they
end up in
landfills.
California is
the only state
which requires
all batteries
be recycled.
If you throw
your small,
used batteries
in the trash,
here is what
happens to
them.
All batteries
are
self-discharging.
That means
even when not
in use, they
leak tiny
amounts of
energy. You
have likely
ruined a
flashlight or
two from an
old, ruptured
battery. When
a battery runs
down and can
no longer
power a toy or
light, you
think of it as
dead; well, it
is not. It
continues to
leak small
amounts of
electricity.
As the
chemicals
inside it run
out, pressure
builds inside
the battery’s
metal casing,
and
eventually, it
cracks. The
metals left
inside then
ooze out. The
ooze in your
ruined
flashlight is
toxic, and so
is the ooze
that will
inevitably
leak from
every battery
in a landfill.
All batteries
eventually
rupture; it
just takes
rechargeable
batteries
longer to end
up in the
landfill.
In addition to
dry cell
batteries,
there are also
wet cell ones
used in
automobiles,
boats, and
motorcycles.
The good thing
about those
is, ninety
percent of
them are
recycled.
Unfortunately,
we do not yet
know how to
recycle
batteries like
me or care to
dispose of
single-use
ones properly.
But that is
not half of
it. For those
of you excited
about electric
cars and a
green
revolution, I
want you to
take a closer
look at
batteries and
windmills and
solar panels.
These three
technologies
share what we
call
environmentally
destructive
embedded
costs.”
NM got redder
as he spoke.
“Everything
manufactured
has two costs
associated
with it,
embedded costs
and operating
costs. I will
explain
embedded costs
using a can of
baked beans as
my subject.
In this
scenario,
baked beans
are on sale,
so you jump in
your car and
head for the
grocery store.
Sure enough,
there they are
on the shelf
for $1.75 a
can. As you
head to the
checkout, you
begin to think
about the
embedded costs
in the can of
beans.
The first
cost is the
diesel fuel
the farmer
used to plow
the field,
till the
ground,
harvest the
beans, and
transport them
to the food
processor. Not
only is his
diesel fuel an
embedded cost,
so are the
costs to build
the tractors,
combines, and
trucks. In
addition, the
farmer might
use a nitrogen
fertilizer
made from
natural gas.
Next is the
energy costs
of cooking the
beans, heating
the building,
transporting
the workers,
and paying for
the vast
amounts of
electricity
used to run
the plant. The
steel can
holding the
beans is also
an embedded
cost. Making
the steel can
requires
mining
taconite,
shipping it by
boat,
extracting the
iron, placing
it in a
coal-fired
blast furnace,
and adding
carbon. Then
it’s back on
another truck
to take the
beans to the
grocery store.
Finally, add
in the cost of
the gasoline
for your car.
But wait -
can you guess
one of the
highest but
rarely
acknowledged
embedded
costs?” NM
said, then
gave us about
thirty seconds
to make our
guesses. Then
he flashed his
lights and
said, “It’s
the
depreciation
on the
5000-pound car
you used to
transport one
pound of
canned beans!”
NM took on a
golden glow,
and I thought
he might have
winked. He
said, “But
that can of
beans is
nothing
compared to
me! I am
hundreds of
times more
complicated.
My embedded
costs not only
come in the
form of energy
use; they come
as
environmental
destruction,
pollution,
disease, child
labor, and the
inability to
be recycled.”
He paused, “I
weigh one
thousand
pounds, and as
you see, I am
about the size
of a travel
trunk.” NM’s
lights showed
he was
serious. “I
contain
twenty-five
pounds of
lithium, sixty
pounds of
nickel, 44
pounds of
manganese, 30
pounds cobalt,
200 pounds of
copper, and
400 pounds of
aluminum,
steel, and
plastic.
Inside me are
6,831
individual
lithium-ion
cells. It
should concern
you that all
those toxic
components
come from
mining. For
instance, to
manufacture
each auto
battery like
me, you must
process 25,000
pounds of
brine for the
lithium,
30,000 pounds
of ore for the
cobalt, 5,000
pounds of ore
for the
nickel, and
25,000 pounds
of ore for
copper. All
told, you dig
up 500,000
pounds of the
earth’s crust
for just - one
- battery.”
He let that
one sink in,
then added, “I
mentioned
disease and
child labor a
moment ago.
Here’s why.
Sixty-eight
percent of the
world’s
cobalt, a
significant
part of a
battery, comes
from the
Congo. Their
mines have no
pollution
controls, and
they employ
children who
die from
handling this
toxic
material. Should
we factor in
these diseased
kids as part
of the cost of
driving an
electric
car?”
NM’s red and
orange light
made it look
like he was on
fire.
“Finally,” he
said, “I’d
like to leave
you with these
thoughts.
California is
building the
largest
battery in the
world near San
Francisco, and
they intend to
power it from
solar panels
and windmills.
They claim
this is the
ultimate in
being ‘green,’
but it is not!
This
construction
project is
creating an
environmental
disaster. Let
me tell you
why.
The main
problem with
solar arrays
is the
chemicals
needed to
process
silicate into
the silicon
used in the
panels. To
make pure
enough silicon
requires
processing it
with
hydrochloric
acid, sulfuric
acid, nitric
acid, hydrogen
fluoride,
trichloroethane,
and acetone.
In addition,
they also need
gallium,
arsenide,
copper-indium-gallium-
Windmills are
the ultimate
in embedded
costs and
environmental
destruction.
Each weighs
1688 tons (the
equivalent of
23 houses) and
contains 1300
tons of
concrete, 295
tons of steel,
48 tons of
iron, 24 tons
of fiberglass,
and the hard
to extract
rare earths
neodymium,
praseodymium,
and
dysprosium.
Each blade
weighs 81,000
pounds and
will last 15
to 20 years,
at which time
it must be
replaced. We
cannot recycle
used blades.
Sadly, both
solar arrays
and windmills
kill birds,
bats, sea
life, and
migratory
insects.
NM lights
dimmed, and he
quietly said,
“There may be
a place for
these
technologies,
but you must
look beyond
the myth of
zero
emissions. I
predict EVs
and windmills
will be
abandoned once
the embedded
environmental
costs of
making and
replacing them
become
apparent. I’m
trying to do
my part with
these
lectures.
Thank you for
your
attention,
good night,
and good
luck.” NM’s
lights went
out, and he
was quiet,
like a regular
battery.
