Moment resistance and rotation capacity of semi-rigid composite connections with precast hollowcore slabs.

Fu, F., Lam, Dennis, Ye, J.

January 2010

Semi-rigid composite connections with precast hollowcore slabs are a newly developed technique with few applications in current construction practice. The research on the structural behaviour of this new type of connection is limited, with no existing method available to predict its important characteristics such as moment and rotation capacities. In this paper, based on the parametric studies of the three-dimensional finite element model and full-scale tests, analytical methods to calculate the moment and rotation capacity of this type of composite joint are proposed. A comparison between the proposed calculation method and the full-scale test results was made, and good agreement was obtained.

Structural behaviour of concrete-filled elliptical column to I-beam connections

Yang, Jie

January 2017

Concrete-filled tubular (CFT) columns have been widely adopted in building structures owing to their superior structural performance, such as enhanced load bearing capacity, compared to hollow tubes. Circular, square and rectangular hollow sections are most commonly used in the past few decades. Elliptical hollow section (EHS) available recently is regarded as a new cross-section for the CFT columns due to its attractive appearance, optional orientation either on major axis or minor axis and improved structural efficiency. The state of the research in terms of elliptical columns, tubular joints between EHSs and connections with CFT columns, etc., are reviewed in this thesis, showing a lack of investigations on EHSs, especially on beam to elliptical column connections which are essential in framed structures. The structural behaviour of elliptical column to I-beam connections under bending is studied in this thesis to fill the research gap. Overall ten specimens with various joint assemblies were tested to failure to highlight the benefits of adopting concrete infill and stiffeners in the columns. A three-dimensional finite element model developed by using ABAQUS software is presented and verified against obtained experimental results, which shows acceptable accuracy and reliability in predicting failure modes of the connections and their moment capacities. Parametric studies were performed to access the main parameters that affecting the bending behaviour of the connections. A simple hand calculation method in terms of ultimate moment capacity is proposed according to experiments conducted for connections with concrete-filled columns.

The impact of connection stiffness on the global structural behavior in a CLT building : A combined experimental-numerical study

Abrahamsson, Jenny, la Fleur, Filip

January 2021

Cross Laminated Timber (CLT) has in recent years become a more important building material. This means that the demand for accurate calculation methods in building standards such as Eurocode 5 has increased. There is limited knowledge about the connections in CLT buildings which is an important part of a CLT structure. This thesis was therefore focused on investigating a wall-floor-wall type connection commonly found in platform type buildings.  An experimental and numerical study on typical wall-floor-wall connections was carried out in this thesis. In the experimental part 60 tests with 8 different configurations were conducted to investigate the influence of different parameters on the connection, moment capacity and rotational stiffness. During the tests the deformation of the specimens under four load levels were investigated. Compression tests were also performed on the specimens to determine the compressive strength and stiffness of the elements. In the numerical part two different models for the connection were created. One simplified model with rotational springs and one more complex model with compression springs. With these models the influence from the number of stories, span and thickness of the wall on the global behavior of a structure was investigated.  The result from this thesis shows that there is both moment capacity and rotational stiffness in the wall-floor-wall type connection that can be utilized in the design phase of a structure. This was proven by both the experimental and the numerical study. The parameters that influence the behavior of the connection most were the load level applied on the wall and the wall thickness. The model created in the numerical study showed great potential regarding the replication of the connection behavior observed in the experimental study.

CLT

Cross Laminated Timber

Connection

Rotational Stiffness

Moment Capacity

Modelling

FEM.

Building Technologies

Husbyggnad

¿Behaviour of semi-rigid composite beam ¿ column connections with steel beams and precast hollow core slabs.

Lam, Dennis, Fu, F.

January 2006

This paper is concerned with the behaviour of beam ¿ column connections of steel ¿ concrete composite beams with precast hollow core slabs. Experiments were carried out to investigate the joint rotation characteristics and ultimate moment capacity of these connections. Details of the test specimens, instrumentation, test set-up and test procedures are described. Results obtained for the connection moment capacity, rotation capacity and failure modes are presented. It is found that through proper design and detailing, these simple steel connections display the characteristics of a semi-rigid connection with very little extra cost.

Beam - column connections

Steel - concrete composite beams

Precast hollow core slabs

Joint rotation characteristics

Moment capacity

Flexural performance of FRP reinforced concrete beams

Kara, Ilker F., Ashour, Ashraf

04 1900

yes / A numerical method for estimating the curvature, deflection and moment capacity of FRP reinforced concrete beams is developed. Force equilibrium and strain compatibility equations for a beam section divided into a number of segments are numerically solved due to the non-linear behaviour of concrete. The deflection is then obtained from the flexural rigidity at mid-span section using the deflection formula for various load cases. A proposed modification to the mid-span flexural rigidity is also introduced to account for the experimentally observed wide cracks over the intermediate support of continuous FRP reinforced concrete beams. Comparisons with experimental results show that the proposed numerical technique can accurately predict moment capacity, curvature and deflection of FRP reinforced concrete beams. The ACI-440.1R-06 equations reasonably predicted the moment capacity of FRP reinforced concrete beams but progressively underestimated the deflection of continuous ones. On the other hand, the proposed modified formula including a correction factor for the beam flexural rigidity reasonably predicted deflections of continuous FRP reinforced concrete beams. It was also shown that a large increase in FRP reinforcement slightly increases the moment capacity of FRP over-reinforced concrete beams but greatly reduces the defection after first cracking.

Structural Behaviour of Concrete-filled Elliptical Column to I-beam Connections

Yang, Jie

January 2017

Concrete-filled tubular (CFT) columns have been widely adopted in building structures owing to their superior structural performance, such as enhanced load bearing capacity, compared to hollow tubes. Circular, square and rectangular hollow sections are most commonly used in the past few decades. Elliptical hollow section (EHS) available recently is regarded as a new cross-section for the CFT columns due to its attractive appearance, optional orientation either on major axis or minor axis and improved structural efficiency. The state of the research in terms of elliptical columns, tubular joints between EHSs and connections with CFT columns, etc., are reviewed in this thesis, showing a lack of investigations on EHSs, especially on beam to elliptical column connections which are essential in framed structures. The structural behaviour of elliptical column to I-beam connections under bending is studied in this thesis to fill the research gap. Overall ten specimens with various joint assemblies were tested to failure to highlight the benefits of adopting concrete infill and stiffeners in the columns. A three-dimensional finite element model developed by using ABAQUS software is presented and verified against obtained experimental results, which shows acceptable accuracy and reliability in predicting failure modes of the connections and their moment capacities. Parametric studies were performed to access the main parameters that affecting the bending behaviour of the connections. A simple hand calculation method in terms of ultimate moment capacity is proposed according to experiments conducted for connections with concrete-filled columns.

Concrete Filled Columns

Elliptical Hollow Section

Moment Capacity

Rotation Capacity

Joint Stiffness

Finite Element Model

STRUCTURAL BEHAVIOR AND DESIGN OF TWO CUSTOM ALUMINUM EXTRUDED SHAPES IN CUSTOM UNITIZED CURTAIN WALL SYSTEMS

WANG, YONGBING

21 July 2006

No description available.

Engineering, Civil

complex thin-walled section

assembled sections

aluminum structural section

moment capacity

Structural, economic and material comparison of various steel grades under fatigue loading

Amobi, Ikechukwu Ugochukwu

28 March 2008

ABSTRACT As industries are upgrading rapidly from a lower steel grade to higher ones it has become necessary to study the effect of changing from lower steel grades to higher grades. This thesis reports on fatigue life and behaviour, economic implications and material composition of these higher strength steels (HSS) as compared to the conventional grades. Three grades are commercially available in South Africa: 300W, 350W and 460W. These different steel grades (conventional and HSS) with the same moment capacities where subjected to constant dynamic stresses and the fatigue crack growth of the overloading and unloading were monitored and compared with each other. The influences of the overloading and unloading made standard grades perform better under repeated loading than the HSS, since HSS have been proved to have poor ductility, resulting in lower number of cycles to failure. An 85% increase in material cost was generated as HSS replaces the conventional lower steel grades. Reduction in number of cycles to failure in HSS was over 500%. A space analysis for a multi-storey building with 10 beam floors was conducted for the various steel grades using a software package. The buckling and linear behaviours of these structures were compared. Although the deflections were not too far apart, it was shown clearly that grade lower steel grades performed better than the higher grades. An optimization was conducted using the parameters discussed in the text or obtained from experiment and computer modelling, in order to aid in the selection criterion of general purpose steel. Grade 300W was the optimal grade although the result was based mainly on the cost and fatigue behaviour of the three grades.

fatigue

steel grades

ductility

HSS

stresses

moment capacity

crack growth

cycles to failure

optimization

buckling

general purpose steel

KOLFIBERFÖRSTÄRKNING – En jämförelse mellan kolfiberförstärkning och traditionella förstärkningsmetoder / CARBON FIBER REINFORCEMENT – A comparison between carbon fiber reinforced poly and traditional reinforcement methods

Barbaranelli, Andreas, Bengtsson, Pär

January 2017

Att en byggnadsdel kan vara i behov av en förstärkning är inte ovanligt i dagsläget. Det kan handla om ett bjälklag som kommer utsättas för mer last då verksamheten ändras från bostad till kontorslandskap. Alternativa lösningar till att förstärka en sådan konstruktion skulle antingen vara att införa stålbalkar och pelare eller gjuta på det befintliga bjälklaget. Det som få konstruktörer och entreprenörer tänker på är att en kolfiberlösning kan vara ett smidigare alternativ. Examensarbetes syfte är att undersöka om kolfiberförstärkningar kan konkurrera med traditionella förstärkningsmetoder. Lyfta fram för-och nackdelar för samtliga förstärkningsmetoder och väga dem mot varandra utifrån en beräkningssynpunkt och utförandemässigt. Metoder för att få en bra förståelse för hur kolfiber höjer böjmomentkapaciteten är laboration med provtryckningar samt beräkningar på ett verkligt broprojekt. I båda fallen har kolfiberlösningen jämförts med traditionella lösningar. Arbetets resultat visar att kolfiberförstärkningar kan, i många fall, ersätta traditionella förstärkningsmetoder. Detta på grund av sin lätta vikt och höga draghållfasthet som gör det möjligt att på ett effektivt sätt höja böjmomentkapaciten hos byggnadsdelar. Enligt laborationen gav kolfiberförstärkningen ungefär samma procentuella ökning i hållfasthet som en plattstålförstärkning. / A building part could need a reinforcement. It could be a system of joists that are soon going to be loaded with heavier loads when business is changing from residence to an office. The alternate solution to reinforce that kind of construction would be with steel beams and columns or increase the height of the floor with more concrete. What few constructors and contractors know are the solution with carbon fiber reinforcement could be a better alternative. The purpose of the thesis is to study if carbon fiber reinforcement could compete with traditional reinforcement methods. From a calculating and a work-related perspective the project will underline the pro and cons with all of the reinforcement methods. To demonstrate how carbon fiber increase the bending moment capacity have lab and calculation of a real bridge project been executed. In both cases have a carbon fiber solution been compared with traditional reinforcement methods. The result of the thesis shows that carbon fiber reinforcement could replace traditional methods in many cases. The pros with the carbon fiber reinforcement is the light weight and high tensile strength that makes it possible, on an efficient way, increase the bending moment capacity in a building part. The thesis lab result shows that a carbon fiber reinforcement does have the same percentage increase in strength as a flat steel reinforcement.

carbon fiber

concrete construction

reinforcement

bending moment capacity

epoxy

Kolfiber

betongkonstruktion

förstärkning

böjmomentkapacitet

epoxi

hållfasthet

Civil Engineering

Samhällsbyggnadsteknik

Carbon Fiber Reinforced Polymer Repairs of Impact-Damaged Prestressed I-Girders

Brinkman, Ryan J.

January 2012

No description available.

Civil Engineering

Carbon Fiber Reinforced Polymer Repair

CFRP Repair

Ultimate Moment Capacity

Prestressed Concrete Bridge I-girders

Impact-Damage