Your search keyword '"Pecka Ján"' showing total 3 results

1. Durability of FRP Reinforcements and Long-Term Properties

Author

Gajdošová Katarína, Sonnenschein Róbert, Blaho Stanislav, Kinčeková Simona, and Pecka Ján

Subjects

gfrpreinforcement, long-term properties, creep-rupture, long-term reduction factors, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Although fiber-reinforced polymers (FRPs) have achieved increasing popularity in strengthening concrete structures and reinforcing new ones, there is to date insufficient knowledge about their long-term behavior. The long-term properties of FRPs specified in design codes lead to the low utilization capacity of these materials and are not supposed to be correct according to the actual behavior of structures reinforced with FRPs after 20 or 30 years of their use. Environmental impact reduction factors limit the mechanical properties of FRP composites in a range from 0.95 for CFRP to 0.5 for GFRP; the creep rupture factor is from 0.9 to 0.2. The paper summarizes previous research and experimental studies on the long-term properties of FRP reinforcements and also their comparison with the actual structures in which this reinforcement has been used; it presents the first part of an experimental investigation with comparative calculations.

Published

2020

2. Parametric study on strengthening slender reinforced-concrete columns.

Author

Pecka, Ján, Gajdošová, Katarína, and Štefanovičová, Michaela

Subjects

*STRUCTURAL failures, *CONCRETE columns, *AXIAL loads, *STRUCTURAL steel, *REINFORCED concrete, *CONCRETE-filled tubes, *COMPRESSIVE strength

Abstract

Columns are slender vertical load-bearing members, designed with a high degree of utilization of their design resistance. They are efficiently used especially in buildings, where it is a requirement to create free dispositions. Their disadvantage is that they only have a small reserve in resistance, so it is often necessary to proceed to their renovation or strengthening. The requirement for strengthening may be based on the need for repair of a structural failure, to repair mistakes during design or construction, but also on the need for an increase in the resistance of existing structure resulting from a change in its load. There are several methods to choose from, when the strengthening of a column is needed. Traditional methods include enlargement of the original cross-section with the addition of concrete or structural steel members. These solutions increase the compression as well as the bending resistance of the column, but there is a significant increase in the cross-sectional area of the column. Newer methods use progressive materials that allow the required strengthening to be achieved with lower or almost zero cross-sectional enlargement. These methods include the application of FRP composites, but also the use of FRC or ferrocement. Mostly CFRP (Carbon Fiber Reinforced Polymer) strips and sheets are used for strengthening. The strips can be installed by NSMR or EBR method. They serve as additional tensile reinforcement. Sheets can also be bonded in the longitudinal direction as an additional tensile reinforcement, but they are more often applied in the transverse direction in the form of stirrups or helices, thus creating a wrap around the column. When column is then loaded with an axial force, the sheets prevent transverse deformation, a spatial state of stress occurs, which leads to an increase in the compressive strength of concrete. In addition to CFRP sheets, FRC or ferrocement can also be used for wrapping. This article deals with slender columns strengthening. The simple parametric study compares the influence on column resistance by the change of following parameters: concrete compressive strength, amount of reinforcement in the cross-section, and amount of reinforcement added to the cross-section surface, the results are presented by means of interaction diagrams of the column cross-section and the interaction diagrams of the column taking into account the second order effects. The comparison shows that for slender columns a more significant increase in the resistance of the column is achieved by adding longitudinal reinforcement. The increase in the strength of the concrete (achieved by wrapping) has only a minimal effect on the resistance increase of the column. [ABSTRACT FROM AUTHOR]

Published

2023

3. The use of a general method for calculating the resistance of strengthened concrete columns

Author

Pecka Jan and Gajdosova Katarina

Subjects

Engineering (General). Civil engineering (General), TA1-2040

Abstract

Columns are one of the basic types of vertical load-bearing elements. In buildings, they are used where there is a requirement to create free spaces. This results in an effort to minimize the cross-section dimensions of the column and to maximize the use of its resistance. The need of the increase in resistance is the reason for columns strengthening. The choice of a suitable strengthening method must take into account the way the column is loaded. Some methods are universal, the others are more effective in the case of predominant compressive, or predominant bending loading. In presented research, the attention is focused on strengthening slender reinforced concrete columns by progressive methods - FRP (fibre reinforced polymer) and FRC (fibre reinforced concrete) applications. For slender columns, second-order effects must be taken into account. The current Eurocode lists three methods of analysing these effects. The simplified methods proposed for the analysis of a reinforced concrete column cannot be applied directly to the calculation of the resistance of a column strengthened by any of the progressive methods. The article is devoted to the calculation of column resistance using a general method that allows the contribution to column resistance from strengthening to be considered.

Published

2023