Gyroscopic exercise tool

Last updated April 10, 2024

A gyroscopic wrist exerciser. Gyrotwister.jpg — A gyroscopic wrist exerciser.

Video showing the use - from starting the rotation with a 'shoestring' over various movements with the holding hand until stopping the rotor with the second hand. The demonstrated speeds are, in part, very high and not recommended for normal exercise due to the high resulting forces.

A Gyroscopic Exercise Tool is a specialized device used in physical therapy to improve wrist strength, promoting the development of palm, forearm, and finger muscles. It can also be used as a unique demonstration of some aspects of rotational dynamics. The device consists of a tennis ball-sized plastic or metal shell surrounding a free-spinning mass, with an inner heavy core, which can be spun by a short rip string. Once the gyroscope inside is going fast enough, the person holding the device can accelerate the spinning mass to high rotation rates by moving the wrist in a circular motion. The force enacted on the user increases as the speed of the inner gyroscope increases.

Mechanics

Inside the outer shell, the spinning mass is fixed to a thin metal axle, each end trapped in a circular, equatorial groove in the outer shell. A lightweight ring with two notches for the axle ends rests in the groove. This ring can slip in the groove, allowing for the ball to spin perpendicular to the rotational axis of the ring.

The only possible way to increase the rate of rotation of the ball is for the sides of the groove to exert forces on the ends of the axle. The normal and axial forces will have no effect, so the tangential force must be provided by the friction of the ring acting on the axle. The user can apply a torque on the ball by tilting the shell in any direction except in the plane of the groove or around an axis aligned with the axle. The tilting results in a shift of the axle ends along the groove. The direction and speed of the shift can be found from the formula for the precession of a gyroscope: the applied torque is equal to the cross product of the angular velocity of precession and the angular momentum of the spinning mass. The rate of rotation of the internal ball increases as the total amount of torque applied is increased. The direction of the torque does not matter, as long as it is perpendicular to the plane of rotation of the ball. The friction of the ring increases on the other side of the side opposite to the plane of rotation. This process obeys symmetry across the plane perpendicular to the axle. The only restriction to this process is that the relative speed of the surface of the axle and the side of the groove due to precession, ${\mathit {\Omega }}_{\mathrm {P} }R_{\mathrm {groove} }$ , must exceed the relative speed due to the rotation of the spinning mass, $\omega r_{\mathrm {axle} }$ . The minimum torque required to meet this condition is $I\omega ^{2}\left(r_{\mathrm {axle} }/R_{\mathrm {groove} }\right)$ , where I is the moment of inertia of the spinning mass, and ω is its angular velocity.

Since the rotation will accelerate regardless of the direction of the applied torque, as long as it is large enough, the device will function without any fine-tuning of the driving motion. The tilting of the shell does not have to have a particular rhythm with the precession or even have the same frequency. Since sliding (kinetic) friction is usually nearly as strong as static (sticking) friction for the materials usually used, it is not necessary to apply precisely the value of torque which will result in the axle rolling without slipping along the side of the groove. These factors allow beginners to learn to speed up the rotation after only a few minutes of practice.

By applying the proportionality of the force of friction to the normal force, $F_{\mathrm {f} }=\mu _{\mathrm {k} }F_{\mathrm {n} }$ , where $\mu _{\mathrm {k} }$ is the kinetic coefficient of friction, it can be shown that the torque spinning up the mass is a factor of $\mu _{\mathrm {k} }\left(r_{\mathrm {axle} }/R_{\mathrm {groove} }\right)$ smaller than the torque applied to the shell. Since frictional force is essential for the device's operation, the groove must not be lubricated as to allow for the friction of the ring to enact a force on the gyro.^[1]^[2]^[3]^[4]^[5]

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References

↑ Higbie, J. (February 1, 1980). "The Physics of the Dyna Bee". The Physics Teacher. 18 (2): 147–8. Bibcode:1980PhTea..18..147H. doi:10.1119/1.2340452. ISSN 0031-921X.
↑ Heyda, P. G. (2000). "Roller Ball Dynamics". Mathematics Today. 36 (9).
↑ Heyda, P. G. (October 1, 2002). "Roller Ball Dynamics Revisited". American Journal of Physics. 70 (10): 1049–51. Bibcode:2002AmJPh..70.1049H. doi:10.1119/1.1499508. ISSN 0002-9505.
↑ Gulick, D. W.; O’Reilly, O. M. (June 1, 2000). "On the Dynamics of the Dynabee". Journal of Applied Mechanics. 67 (2): 321–5. Bibcode:2000JAM....67..321G. doi:10.1115/1.1304914. ISSN 0021-8936.
↑ Petrič, Tadej; Curk, Boris; Cafuta, Peter; Žlajpah, Leon (June 1, 2010). "Modelling of the Robotic Powerball®: A Nonholonomic, Underactuated and Variable Structure-Type System". Mathematical and Computer Modelling of Dynamical Systems. 16 (4): 327–346. doi:10.1080/13873954.2010.484237. hdl: 10.1080/13873954.2010.484237 . S2CID 120513329.

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[1] Higbie, J. (February 1, 1980). "The Physics of the Dyna Bee". The Physics Teacher. 18 (2): 147–8. Bibcode:1980PhTea..18..147H. doi:10.1119/1.2340452. ISSN 0031-921X.

[2] Heyda, P. G. (2000). "Roller Ball Dynamics". Mathematics Today. 36 (9).

[3] Heyda, P. G. (October 1, 2002). "Roller Ball Dynamics Revisited". American Journal of Physics. 70 (10): 1049–51. Bibcode:2002AmJPh..70.1049H. doi:10.1119/1.1499508. ISSN 0002-9505.

[4] Gulick, D. W.; O’Reilly, O. M. (June 1, 2000). "On the Dynamics of the Dynabee". Journal of Applied Mechanics. 67 (2): 321–5. Bibcode:2000JAM....67..321G. doi:10.1115/1.1304914. ISSN 0021-8936.

[5] Petrič, Tadej; Curk, Boris; Cafuta, Peter; Žlajpah, Leon (June 1, 2010). "Modelling of the Robotic Powerball®: A Nonholonomic, Underactuated and Variable Structure-Type System". Mathematical and Computer Modelling of Dynamical Systems. 16 (4): 327–346. doi:10.1080/13873954.2010.484237. hdl: 10.1080/13873954.2010.484237 . S2CID 120513329.

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