The long span problem in the analysis of conductor vibration damping

Author

Rawlins, Charles B.

Author_Institution

Alcoa Conductor Accessories, Spartanburg, SC, USA

Volume

15

Issue

2

fYear

2000

fDate

4/1/2000 12:00:00 AM

Firstpage

770

Lastpage

776

Abstract

In analysis of vibration damping of overhead spans, expected severity is determined on the basis of the balance of vibration power supplied by the wind through vortex shedding against dissipation by self damping in the conductor and by damping devices. Conventional practice is to approximate the vibration of the span as a series of sine-shaped loops, all of equal amplitude, for purposes of estimating wind input and self damping. However, for long spans requiring efficient damping, most of the loops are not sine shaped, and loop amplitude varies along the span. The effects of these differences are explored by representing the vibration as opposite-moving waves that grow as they travel. Nonlinearity in the wind excitation and self damping functions is taken into account. Results show that so-called long span effects significantly reduce required span-end damping in long spans

Keywords

damping; overhead line conductors; overhead line mechanical characteristics; power overhead lines; vibrations; vortices; wind; Aeolian vibrations; conductor vibration damping analysis; damping devices; dissipation; linear analysis; long span; opposite-moving waves; self damping; self damping functions; sine-shaped loops; vibration damping; vibration power balance; vortex shedding; wind; wind excitation nonlinearity; wind input estimation; Amplitude estimation; Conductors; Damping; Frequency; Impedance; Power supplies; Propagation constant; Propagation losses; Testing; Wind energy;

fLanguage

English

Journal_Title

Power Delivery, IEEE Transactions on

Publisher

ieee

ISSN

0885-8977

Type

jour

DOI

10.1109/61.853018

Filename

853018