How rollercoasters affect your body Brian D. Avery
In the summer of 1895,
crowds flooded the Coney Island boardwalk
to see the latest marvel
of roller coaster technology:
the Flip Flap Railway.
This was America’s first-ever looping coaster
– but its thrilling flip came at a price.
The ride caused numerous cases of
severe whiplash,
neck injury and even ejections,
all due to its signature loop.
Today, coasters can pull off
far more exciting tricks,
without resorting to the “thrill”
of a hospital visit.
But what exactly are roller coasters
doing to your body,
and how have they managed to get scarier
and safer at the same time?
At the center of every roller coaster
design is gravity.
Unlike cars or transit trains,
most coasters are propelled around their tracks
almost entirely by gravitational energy.
After the coaster crests the initial lift hill,
it begins an expertly engineered cycle –
building potential energy on ascents
and expending kinetic energy on descents.
This rhythm repeats throughout the ride,
acting out the coaster engineer’s
choreographed dance
of gravitational energy.
But there’s a key variable in this cycle
that wasn’t always so carefully considered:
you.
In the days of the Flip-Flap,
ride designers were most concerned
with coasters getting stuck
somewhere along the track.
This led early builders to overcompensate,
hurling trains down hills
and pulling on the brakes
when they reached the station.
But as gravity affects the cars,
it also affects the passengers.
And under the intense conditions
of a coaster,
gravity’s effects are multiplied.
There’s a common unit used by jet pilots,
astronauts,
and coaster designers called “g force”.
One G force is the familiar tug of gravity
you feel when standing on Earth
– this is the force of Earth’s
gravitational pull on our bodies.
But as riders accelerate and decelerate,
they experience more or less
gravitational force.
Modern ride designers know that the
body can handle up to roughly 5 Gs,
but the Flip-Flap and its contemporaries
routinely reached up to 12 Gs.
At those levels of gravitational pressure,
blood is sent flying from your brain
to your feet,
leading to light-headedness or blackouts
as the brain struggles to stay conscious.
And oxygen deprivation in the retinal cells
impairs their ability to process light,
causing greyed out vision or temporary blindness.
If the riders are upside down,
blood can flood the skull,
causing a bout of crimson vision
called a “redout”.
Conversely, negative G’s
create weightlessness.
Within the body,
short-term weightlessness
is mostly harmless.
It can contribute to a rider’s
motion sickness
by suspending the fluid in
their inner ears
which coordinates balance.
But the bigger potential danger
– and thrill –
comes from what ride designers
call airtime.
This is when riders typically
experience seat separation,
and, without the proper precautions,
ejection.
The numerous belts and harnesses
of modern coasters
have largely solved this issue,
but the passenger’s ever-changing position
can make it difficult
to determine what needs to be
strapped down.
Fortunately, modern ride designers
are well aware
of what your body, and the coaster,
can handle.
Coaster engineers play these competing
forces against each other,
to relieve periods of intense pressure
with periods of no pressure at all.
And since a quick transition from
positive to negative G-force
can result in whiplash, headaches,
and back and neck pain,
they avoid the extreme changes
in speed and direction
so common in thrill rides of old.
Modern rides are also much sturdier,
closely considering the amount
of gravity they need to withstand.
At 5 G’s, your body feels 5 times heavier;
so if you weigh 100lbs,
you’d exert the weight of 500 lbs
on the coaster.
Engineers have to account for
the multiplied weight
of every passenger when designing
a coaster’s supports.
Still, these rides aren’t for everyone.
The floods of adrenaline,
light-headedness, and motion sickness
aren’t going anywhere soon.
But today’s redundant restraints,
3D modeling and simulation software
have made roller coasters safer
and more thrilling than ever.
Our precise knowledge about the
limits of the human body
have helped us build coasters that are
faster, taller, and loopier
– and all without going off the rails.