HARMONİK ETKİ ALTINDAKİ ANA YAPILAR İÇİN OPTİMUM PASİF AYARLI KÜTLE SÖNÜMLEYİCİ SİSTEMLER

Year 2021, Volume: 9 Issue: 4, 1062 - 1071, 20.12.2021

Onur Araz

https://doi.org/10.21923/jesd.888880

Cited By: 6

Abstract

Tek bir ayarlı kütle sönümleyicinin (AKS) etkinliğini ve sağlamlığını artırmak için, AKS’ler ana sisteme paralel ya da seri olarak bağlanırlar. Paralel bağlı AKS’lerden farklı olarak seri bağlı AKS’ler ana sisteme seri olarak bağlı iki farklı AKS’den meydana gelmektedir. Bu çalışmada seri ve paralel bağlı AKS'lerin optimum parametreleri benzetilmiş tavlama algoritması kullanılarak elde edilmiştir. Optimum parametrelerin elde edilmesinde ana sistemdeki yer değiştirmenin en aza indirilmesi amaçlanmıştır. Ayrıca, her iki AKS cihazının optimum tasarımı için kolayca kullanılabilen açık formüller, eğri uydurma tekniği kullanılarak türetilmiştir. Optimum seri bağlı AKS sisteminin kontrol performansı sayısal analizlerle doğrulanmış ve klasik AKS ve paralel bağlı AKS ile karşılaştırılmıştır.

Keywords

Ayarlı Kütle Sönümleyici, Dinamik Davranış, Optimizasyon, Optimum Parametre, Benzetilmiş Tavlama

OPTIMUM PASSIVE TUNED MASS DAMPER SYSTEMS FOR MAIN STRUCTURES UNDER HARMONIC EXCITATION

Abstract

To increase the effectiveness and robustness of a single Tuned mass damper (TMD), TMDs are connected in series or parallel to the main system. Unlike parallel TMDs (PTMD), series TMDs (STMD) consist of only two different TMD units, each of which is connected to the main structure in series. The optimum parameters of series and parallel TMDs are obtained by using the simulated annealing (SA) algorithm in this study. It is aimed to minimize the displacement in the main system in obtaining the optimum parameters. Also, the explicit formulas that can be easily used for the optimum design of both TMD devices are derived using the curve-fitting technique. The control performance of the optimum STMD device is confirmed through numerical analyses and compared with classical TMD and PTMD.

Keywords

Tuned Mass Damper, Dynamic Response, Optimization, Optimum Parameter, Simulated Annealing

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