Inerter (mechanical networks)

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Inerter device being used to mechanically isolate vibration at a given frequency.

In the study of mechanical networks in control theory, an inerter is a two-terminal device in which the forces applied at the terminals are equal, opposite, and proportional to relative acceleration between the nodes. Under the name of J-damper the concept has been used in Formula 1 racing car suspension systems.

Contents

It can be constructed with a flywheel mounted on a rack and pinion. It has a similar effect to increasing the inertia of the sprung object.

Discovery

Malcolm C. Smith, a control engineering professor at the University of Cambridge, first introduced inerters in a 2002 paper. [1] Smith extended the analogy between electrical and mechanical networks (the mobility analogy). He observed that the analogy was incomplete, since it was missing a mechanical device playing the same role as an electrical capacitor. The analogy makes mass the analogy of capacitance, but the capacitor representing a mass always has one terminal connected to ground potential. In a real electrical network, capacitors can be connected between any two arbitrary potentials, they are not limited to ground. Noticing this, Smith set about finding a mechanical device that was a true analog of a capacitor. He found that he could construct such a device using gears and flywheels, one of several possible methods.

The constitutive equation is,

,

where the constant b is the inertance and has units of mass.

Construction

A linear inerter can be constructed by meshing a flywheel with a rack gear. The pivot of the flywheel forms one terminal of the device, and the rack gear forms the other.

A rotational inerter can be constructed by meshing a flywheel with the ring gear of a differential. The side gears of the differential form the two terminals.

Applications

Shortly after its discovery, the inerter principle was used under the code name of J-damper in the suspension systems of Formula 1 racing cars. When tuned to the natural oscillation frequencies of the tires, the inerter reduced the mechanical load on the suspension. McLaren Mercedes began using a J-damper in early 2005, and Renault shortly thereafter. [2] [3] J-dampers were at the center of the 2007 Formula One espionage controversy which arose when Phil Mackereth left McLaren for Renault.

Researchers are developing new vibration-control devices based on inerters to build high-rise skyscrapers which can withstand high winds. [4] [5]

See also

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References

  1. Smith, M. C. (2002). "Synthesis of mechanical networks: The inerter". IEEE Transactions on Automatic Control. 47 (10): 1648–1662. doi:10.1109/TAC.2002.803532.
  2. Wagner, Siobhan (September 1, 2008). "Shock tactics" . The Engineer . Vol. 293. p. 34. ISSN   0013-7758 via EBSCOhost.
  3. Chen, M.; Papageorgiou, C.; Scheibe, F.; Wang, F. C.; Smith, M. (2009). "The missing mechanical circuit element" (PDF). IEEE Circuits and Systems Magazine. 9: 10–26. doi:10.1109/MCAS.2008.931738. S2CID   3783744.
  4. Petrini, Francesco; Giaralis, Agathoklis; Wang, Zixiao (2020). "Optimal tuned mass-damper-inerter (TMDI) design in wind-excited tall buildings for occupants' comfort serviceability performance and energy harvesting" (PDF). Engineering Structures. 204: 109904. Bibcode:2020EngSt.20409904P. doi:10.1016/j.engstruct.2019.109904. S2CID   213743645.
  5. "Formula 1 technology for the construction of skyscrapers: Civil engineering academic is developing new vibration-control devices based on Formula 1 technology for skyscrapers". ScienceDaily. Retrieved 2020-01-05.