Catching
seems a particularly gruelling part of the trapeze. The
catcher must spend a good proportion of his time on the
trapeze hanging upside down, and when he is not, he can
only sit on the trapeze bar, which is very hard and not
kind on the buttocks.
Catchers seem to have to have
great deal of strength in their arms, since they must be
able to climb up a rope to get to the catch trap (this looks
best if done in a piked position: without using the legs).
They must also be able to support the weight of the performers
they catch. I did some brief experimentation with catching,
and I found that if you try to support the weight of even
small children, when you are hanging from your knees, this
causes stress on your knee-joints which makes them very
painful afterwards. The catcher's lock (the position used
on the flying trapeze) is adapted so the bar rests on the
front of your thighs, preventing this stress on the knees.
How much weight must you be able to support
in this position:
Let us assume that a heavy person weighs
100kg.
We
know that the point where most centripetal force acts is
at the point of highest speed (see Investigation 7).
The catcher and the flyer will be modelled
as a pendulum, length 3.8m, and with mass 170kg (two people).
Since they swing up to approximately the same angle as the
fly bar, we can calculate their maximum speed.
Maximum speed v = (2gh)^1/2
v = (2 x 9.8 x 3.8 (1 -
cos(0.83)))^1/2
v = 4.9ms-1
We know that centripetal
force F = mv^2/r
If we use 100kg as m, the mass of the
man, we can find the force due to the motion that the catcher
feels in his arms.
F = 100 x 4.92/3.8
F = 631N but we also need
to add the force due to gravity (1000N).
In total, the catcher must
support a maximum of 1631N on his arms during the swing.
This is the equivalent of hanging from a stationary bar
and supporting two average sized men!
But as you will find if you try to do
pull-ups in the gym, it is much easier to hang from the
bar without moving, than it is to try and support yourself
with bent arms. This is because, when your arms are straight,
the strength comes from the properties of the materials
that make up your arm. Your bones (weight for weight) are
stronger than steel, and the only weak points are the joints.
With your arms bent, you are relying solely on the strength
of your muscles, if they relax then they no longer support
you.
Providing
the catcher can keep his arms straight throughout the catch,
then he can rely on the strength of his arms to spread the
force along his body, and not his muscles, which concentrate
the force on the joints in his arm (naturally weak points).
This is why it is not a necessity to have immense upper
body strength as a catcher, just a good technique. In fact,
you often find many women catching for this reason. As an
aside, the danger for women catchers is that the catcher's
lock position can damage your hips and cause complications
in childbirth.
Timing is crucial
The
need to catch with straight arms highlights another reason
why timing is crucial. If you have a ball attached to a
string, which you want to make perform circular motion about
a fixed point, you ideally pull the string taut, and throw
the ball perpendicular to the string (on a tangent to the
proposed circle). If you were instead to throw the ball
into the circle, it would move until the string became taut,
and would jolt the string (the component of the momentum
along the length of the string being lost) and would continue
round the circle at a greatly reduced rate.
The same principal can be applied to catching. If the catch
is made at the point at which the flyer has no forward motion,
he is moving only downwards (i.e. approximately tangentially
to catch trap) this will mean he performs the smoothest
arc, and there is no jolt on the catcher's arms. If he lets
go too early, and flies into the circle, providing he does
not hit the catcher and is able to be caught, there will
be a jolt on the catcher's arms as the arms exert an impulse
to destroy any momentum that is not tangential. Not only
will this be painful on the arms of the catcher, but it
will also reduce the speed of the swing performed by the
catcher and the flyer together, reducing the chances of
a return to the fly bar.
Catching
seems a particularly gruelling part of the trapeze. The
catcher must spend a good proportion of his time on the
trapeze hanging upside down, and when he is not, he can
only sit on the trapeze bar, which is very hard and not
kind on the buttocks. 
We
know that the point where most centripetal force acts is
at the point of highest speed (see Investigation 7).
Providing
the catcher can keep his arms straight throughout the catch,
then he can rely on the strength of his arms to spread the
force along his body, and not his muscles, which concentrate
the force on the joints in his arm (naturally weak points).
This is why it is not a necessity to have immense upper
body strength as a catcher, just a good technique. In fact,
you often find many women catching for this reason. As an
aside, the danger for women catchers is that the catcher's
lock position can damage your hips and cause complications
in childbirth. 
The
need to catch with straight arms highlights another reason
why timing is crucial. If you have a ball attached to a
string, which you want to make perform circular motion about
a fixed point, you ideally pull the string taut, and throw
the ball perpendicular to the string (on a tangent to the
proposed circle). If you were instead to throw the ball
into the circle, it would move until the string became taut,
and would jolt the string (the component of the momentum
along the length of the string being lost) and would continue
round the circle at a greatly reduced rate.