Iš anksto įtemptųjų gelžbetoninių elementų įtempių ir deformacijų apskaičiavimo sluoksnių modelis / Layer Model for Stress and Strain Analysis of Prestressed Concrete Members

Zamblauskaitė, Renata

11 November 2005

Application of refined ultimate state theories and use of high strength materials have resulted in longer spans and smaller depths of reinforced and prestressed concrete structures. Consequently, the condition of the limiting deflection rather than the strength requirement often is the governing design criterion. Long-term deflections might be up to 3 to 4 times larger than the short-term deflections. Such increments are caused by complex physical effects such as concrete creep, shrinkage and cracking, bond defects, etc. Long-term concrete creep and shrinkage deformations govern prestress losses. Structural analysis can be carried out either by traditional design code methods or numerical techniques. Although design code methods ensure safe design, they have significant limitations. Different techniques are used for strength, deflection, crack width and prestress loss analyses. Besides, most of the simplified approaches do not assess such factors as concrete shrinkage, cracking or tension stiffening. Based on a large number of empirical expressions and factors, they lack physical interpretation and do not reveal the actual stress-strain state of cracked structures. On the other hand, numerical techniques are universal and can take into account each physical effect. However, inadequacies made in the prediction of each effect might lead to significant inaccuracies when integral magnitudes such as deflection are to be assessed. Consequently, the predictions by the numerical... [to full text]

Civil Enginering

Valkšnumas

Supleišėjusio tempiamojo betono įtaka

Traukimasis

Kreivis

Įlinkis

Iš anksto įtemptųjų gelžbetoninių elementų įtempių ir deformacijų apskaičiavimo sluoksnių modelis / Layer Model for Stress and Strain Analysis of Prestressed Concrete Members

Zamblauskaitė, Renata

11 November 2005

Application of refined ultimate state theories and use of high strength materials have resulted in longer spans and smaller depths of reinforced and prestressed concrete structures. Consequently, the condition of the limiting deflection rather than the strength requirement often is the governing design criterion. Long-term deflections might be up to 3 to 4 times larger than the short-term deflections. Such increments are caused by complex physical effects such as concrete creep, shrinkage and cracking, bond defects, etc. Long-term concrete creep and shrinkage deformations govern prestress losses. Structural analysis can be carried out either by traditional design code methods or numerical techniques. Although design code methods ensure safe design, they have significant limitations. Different techniques are used for strength, deflection, crack width and prestress loss analyses. Besides, most of the simplified approaches do not assess such factors as concrete shrinkage, cracking or tension stiffening. Based on a large number of empirical expressions and factors, they lack physical interpretation and do not reveal the actual stress-strain state of cracked structures. On the other hand, numerical techniques are universal and can take into account each physical effect. However, inadequacies made in the prediction of each effect might lead to significant inaccuracies when integral magnitudes such as deflection are to be assessed. Consequently, the predictions by the numerical... [to full text]

Civil Enginering

Tension stiffening

Traukimasis

Kreivis

Shrinkage

Supleišėjusio tempiamojo betono įtaka

Valkšnumas

Curvature

Creep

Prestressed concrete members

įlinkis

Deflection

Tempiamųjų plieno plaušu armuotų gelžbetoninių elementų įtempių ir deformacijų analizė / Stress and strain analysis of steel fiber reinforced concrete members subjected to tension

Repečka, Justinas

19 June 2013

Tiriamajame darbe nagrinėjami tempiamieji plieno plaušu armuoti gelžbetoniniai elementai. Atliekama teorinių skaičiavimo metodų literatūros apžvalga. Darbe gauti nauji eksperimentiniai tempiamųjų plieno plaušu armuotų gelžbetoninių elementų deformacijų duomenys. Iš bandymo rezultatų eliminuojamas betono susitraukimas. Patikslinami Eurokodo 2 ir Model Code tempiamųjų elementų deformacijų skaičiavimo metodai, įvertinant plieno plaušo įtaką. Liekamieji įtempiai apskaičiuojami taikant empirinį metodą. Atliekama teorinių ir eksperimentinių rezultatų palyginamoji analizė. Darbo pabaigoje pateikiami pagrindiniai rezultatai ir išvados. / In this Master Thesis investigation of steel fiber reinforced concrete members subjected to tension is performed. Literature survey on theoretical investigation methods of steel fiber reinforced concrete is done. New experimental data of steel fiber reinforced concrete members subjected to tension is obtained. Concrete shrinkage is eliminated from experimental data.Eurocode 2 and Model Code strain calculation methods of members subjected to tension are adjusted to steel fiber reinforced concrete members. Residual stresses calculated using empirical method. Comperative analysis of experimental and theoretical results is done.

Civil Enginering

Deformacijos

Betono traukimasis

Liekamieji įtempiai

Strain

Concrete shrinkage

Residual stresses