One, try it with a ball. If you alter the axis it's still only one

I don't think it makes any difference what the shape actually is, if it's a rigid one.

I think Drewhound and Jenky must be right, but I too am having trouble visualising it.

If I am driving along in a straight line in a car, each of my front wheels is rotating about its axle.  If I then drive in a curve, the whole wheel is also rotating about the centre of the curve.

So where is the axis of rotation now?  It presumably can't still be the axle itself, but another "virtual" axis which is the resolution of the two rotations.  How do the bearings then still keep turning smoothly with an unaligned axis of rotation?

It must be all 3 rotational axes of freedom at the same time. Has anyone ever seen those 80's disco light balls, the ones with loads of lights on the surface. You spin the centre sphere with the lights up around its axis which is horizontal through the centre. Then you spin up the sphere and its supporting structure about another axis which is vertically through the centre of the sphere. Now you've got the centre sphere spinning about two axes. Only one left.................... I'm thinking.

I still think there can only be one axis of rotation -- as Deamo says, the two will resolve as one diagonal one.

However, I don't think it makes any difference whether the axis is within or outside the object -- rotating about an external point is only adding an on-the-spot rotation and a translation-in-a-curve.

Still can't visualise it though.  I think it works out like vectors -- if you push something north and push it east at the same time it ends up going diagonally north-east -- it can't go two separate ways at once.

I think this is the important bit of the question

"Obviously you can take the object and give it a bit of spin about an axis. From then on, can you apply a force that will make it keep spinning, but also spin about a second plane (i.e. make the original axis rotate"

If you were to put two pins on opposite sides of a ball (though the shape isn't important) you could spin the ball around that axis. If you then have two other pins placed elsewhere and try to spin the ball using them as an axis it isn't going to work. Not very scientific but I can visualise this

Reading my own answer I'm still not sure. You could put the ball in a gimbals like arrangement and spin the whole thing in a different plane. But part of the question is "can you apply a force that will make it keep spinning, but also spin about a second plane (i.e. make the original axis rotate)?"

    I don't think you can apply a single force that would achieve both the motions

Imagine you had a big cermaic ball, which was hollow and their was a cat inside. You spin the ball around is longest horizontal axis relative to the floor (i.e spin it round on the spot currently touching the floor)

The cat, inside, climbs upwards thus altering the vertical axis' movement.

Until the friction of the contact with the floor makes the horizontal spin slow to a stop, then if the cat continually climbs and slips and repeats then the ball would be rotating on two axis'.

Now imagine that you and the ball are both on the inside of a larger ceramic ball, which is pinning along some other diagonal axis for example, then the original ball with the cat inside is actually spinng  in 3 directions.

Add more outer balls to add more axis.

Does that make sense ?

BenDToy, to start with I saw the answer clearly and then confused myself but if you look at NetSquirrel's diagram it's clear it can only rotate about one axis as it's shown

I'm not disputing what you say (I follow that) but I don't think it's what he meant

what in the hell are u going on about CJH?

u can rotate it an infinite number of ways, but only in one way at a time as it would be going in a diagonal direction if you tried to go more than one way