Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
DYNAMIC TESTING OF BRIDGES WITH IMPULSE LOADING
Introduction. This article deals with the practice of applying the method of dynamic testing of bridges, namely, modal control using impulse loading. The possibilities of this method for determining the technical condition of a bridge span structure by determining its natural characteristics: actual stiffness and parameters of natural vibration forms are shown. Problem Statement. The article is devoted to the problem of practical implementation of the latest theoretical developments in the field of diagnostics of the technical condition of road bridges by conducting full-scale dynamic tests. Purpose. The main purpose of the article is to demonstrate the effectiveness of dynamic impulse testing as a method for assessing the technical condition of bridges. The method involves the excitation of vibrations of bridge structures by means of pulse loads, recording the response of the structure and analyzing the data obtained. Materials and methods. The material for this article is the results of field tests of a curved overpass made of monolithic reinforced concrete located near Kyiv. The following research methods were used: information analysis, mathematical modeling, and general methods of theoretical research. Results. The full-scale parameters of the overpass span structure obtained from the results of dynamic tests allowed us to assess the impact of existing defects on its integral stiffness and determine its technical condition. Conclusions. In practice, it has been confirmed that the use of pulse loading allows obtaining good results in the modal control of a span structure of complex geometry and static scheme.
DYNAMIC TESTING OF BRIDGES WITH IMPULSE LOADING
Introduction. This article deals with the practice of applying the method of dynamic testing of bridges, namely, modal control using impulse loading. The possibilities of this method for determining the technical condition of a bridge span structure by determining its natural characteristics: actual stiffness and parameters of natural vibration forms are shown. Problem Statement. The article is devoted to the problem of practical implementation of the latest theoretical developments in the field of diagnostics of the technical condition of road bridges by conducting full-scale dynamic tests. Purpose. The main purpose of the article is to demonstrate the effectiveness of dynamic impulse testing as a method for assessing the technical condition of bridges. The method involves the excitation of vibrations of bridge structures by means of pulse loads, recording the response of the structure and analyzing the data obtained. Materials and methods. The material for this article is the results of field tests of a curved overpass made of monolithic reinforced concrete located near Kyiv. The following research methods were used: information analysis, mathematical modeling, and general methods of theoretical research. Results. The full-scale parameters of the overpass span structure obtained from the results of dynamic tests allowed us to assess the impact of existing defects on its integral stiffness and determine its technical condition. Conclusions. In practice, it has been confirmed that the use of pulse loading allows obtaining good results in the modal control of a span structure of complex geometry and static scheme.
DYNAMIC TESTING OF BRIDGES WITH IMPULSE LOADING
Serhii Zavhorodniy (Autor:in) / Vasyl Redchenko (Autor:in)
2023
Aufsatz (Zeitschrift)
Elektronische Ressource
Unbekannt
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