Durability of Buildings in Urban Environment

Andrei A. Varlamov; Vladimir I. Rimshin; Sergei Y. Tverskoi

doi:10.4028/www.scientific.net/MSF.931.340

Paper Titles

Strength of Flexible Compressed Elements when Changing the Options of Composite Reinforcement and Application of the Load
p.315

The Ways to Reduce the Materials Consumption of Compressed Reinforced Concrete Elements
p.321

The Deformation of Partially Prestressed Elements Subjected to Repeated Static Loads
p.328

Evaluation of the Compressed Reinforced Concrete Elements Dynamic Strength, Taking into Account the Temperature Influence on the Strength and Deformability of Reinforcement Steel and Concrete
p.334

Durability of Buildings in Urban Environment
p.340

Combined Way of Diagnostics of Reinforced Concrete Conical Structures
p.346

Analysis of the Stresses of the Wall of a Steel Water Tower
p.352

Rational Placement of a Steel Fiber in Sections of the Combined and Monolithic Bent Reinforced Concrete Elements
p.358

The Seismic Response Investigation on the Multi-Storey Buildings with Seismically Insulating Rubber-Metal Supports
p.362

HomeMaterials Science ForumMaterials Science Forum Vol. 931Durability of Buildings in Urban Environment

Durability of Buildings in Urban Environment

Abstract:

The longevity forecast is proposed to be implemented on the basis of models of degradation theory. The theory of degradation is developed as a general energy method for estimating the longevity of objects. It is based on the law of conservation of energy. To analyze the longevity of urban environment, it is proposed to adopt the simplest model of theory of degradation. The proposed work provides an explanation for the description of proposed model. The urban environment is divided into a number of simpler systems. The more the degree of system separation into simpler ones, the more accurately one can describe the behavior of the entire system in time. Each simple system is described by the simplest model of degradation theory. The general behavior of the system is understood as a simple sum of individual degradation models. A feature of the proposed theory is that the simplest model can describe the entire system or the sum of its individual parts at once. The model makes it possible to consider the issue of equalizing the longevity of individual systems. The analysis of durability of a multicompartment building is taken as an example. In terms of analyzing the given example, individual stages of systems operation, that are still subject to discussion, are identified.

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Periodical:

Materials Science Forum (Volume 931)

Pages:

340-345

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.931.340

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Online since:

September 2018

Authors:

Andrei A. Varlamov*, Vladimir I. Rimshin, Sergei Y. Tverskoi

Keywords:

Acceleration Energy, Construction, Durability, Energy, Physical Deterioration, Power, Theory of Degradation

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* - Corresponding Author

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