Strength Calculation Model for Standoff Screws in Composite Joists

Mujagic, Ubejd

06 December 2000

The objective of the research reported herein is to present a comprehensive evaluation of all available experimental data from push-out tests utilizing the ELCO Grade 8 standoff screws. The goal is to develop a strength prediction equation and determine reliability parameters compatible with the Load Factor Resistance Design (LRFD) procedure that would allow the use of this shear connector in design of composite floor systems. The study considers results from push-out tests using this type of screw reported by Hankins et al. (1994), Alander et al. (1998), Webler et al. (2000), and Mujagic et al. (2000). Further, this study identifies the limitations in earlier approaches aimed at predicting the strength of standoff screws. An improved strength prediction model is developed that considers all applicable limit states and determines maximum strength of a connector. A reliability study was also conducted to derive strength reduction factors to be used in design. Parameters considered in the model include deck type and geometry, screw height, concrete compressive strength, top chord angle yield strength, and stand-off screw rupture strength. Results from strength prediction model were compared with results from composite joist tests. / Master of Science

Composite Joists

Composite Floor Design

Standoff Screws

Shear Connectors

Vibrations in residential timber floors : A comparison between the current and the revised Eurocode 5

Schirén, Whokko, Swahn, Trixie

January 2019

The European standard Eurocode 5, a design method for timber structures,is currently under revision. In this study the draft for a reviseddesign method for vibrations in timber floors was compared to the currentmethod. The hypothesis of the thesis was that the revised designmethod might force some changes to the present construction practiceand that these changes may carry with them increased costs for the industry.Six common floor structures used in Sweden today were identifiedand for these floors design calculations were made according to the currentand the revised design method. It was checked whether the floorspassed the criteria in the two design methods and a comparison was madefor the only criterion which could be compared between the methods, thepoint load deflection. Floor structures could pass or fail the current designmethod based on two criteria, the point load deflection and the unitimpulse velocity response. All floors passed the current design methodexcept one which had a fundamental frequency below 8 Hz, because ofthe low frequency the current design method was not applicable to thefloor structure. In the revised design method the final result is a responsefactor and based on the response factor floors are given floor performancelevels. The seven step scale for the floor performance level go from I toVII where I is excellent and VII is unacceptable. All floor structures excepttwo achieved an acceptable floor performance level according to therevised design method. The two floors which failed were floors commonlyused in single family houses, they failed for a span length commonly usedtoday. A limited parametric study was performed where it was found thatthe modal mass used had a larger impact on the floor performance levelthan the mass per square meter included. For floors with a fundamentalfrequency above 8 Hz, including a higher mass per square meter resultedin a lower, i.e. better, response factor in all cases except one. For floorswith a fundamental frequency between 4.5 and 8 Hz, a higher mass resultedin a higher, i.e. worse, response factor. The study found that notall floor structures used in Sweden today are acceptable according to therevised design method therefore changes may have to be implemented andthese changes could result in an increased cost.

Building Technologies

Husbyggnad

Floor Vibrations: Girder Effective Moment of Inertia and Cost Study

Warmoth, Francis James

14 February 2002

Studies on the effective moment of inertia of girders that support concrete slabs using joist seats as the horizontal shear connections, and a cost efficiency analysis comparing composite and non-composite floor systems that meet vibrations design standards, were conducted. The first study was undertaken because over-prediction of girder effective moment of inertia was the suspected cause of several recent vibration problems in floors supported by widely spaced LH-series joists. Eight purpose-built floors of the type in question were subjected to experimental tests of girder effective moment of inertia and girder frequency. Frequencies were tested for two live loading cases. Three separate test configurations were made with each floor by changing the seat-to-girder connections between bolted, welded, and reinforced. In the study, 1) the accuracy of the current design practice is assessed, 2) a new relationship was proposed, and 3) suggestions for finite element modeling are made. In recent years, composite construction has been used to improve cost efficiency by reducing structural weight and in some cases by reducing story height. However, vibration problems are a design consideration in composite floors because lighter floors tend to be more lively. It is not clear if cost savings can be made with composite construction if vibrations are considered in the design. To compare the cost of composite and non-composite floors that satisfy AISC/CISC Design Guide criterion for walking excitation, four typical size bays were analyzed using commercial design software that finds the least expensive member configuration for a given bay size. All acceptable bay configurations of member sizes and spacing were evaluated for least non-composite and composite costs, then these results were compared. The findings show that composite construction can be more economical when initial dead load deflections do not control the design. / Master of Science

Floor Vibrations

Composite Construction

Moment of Inertia

Stiffness

Floor Design

Steel Joists

Beton durchwachsen: Ein Kunstobjekt aus Beton, das der Natur Raum gibt

Steffen, Catrina

17 November 2023

Das Thema der Ausschreibung hat mich zu einer Fußbodengestaltung für den öffentlichen Raum inspiriert, die von der Natur durchdrungen und in Besitz genommen werden kann. Die kreisrunde Fläche besteht aus sechs durchbrochenen Betonsegmenten, die in Serie produziert und variabel gestaltet werden können, z. B. mit Mosaiken aus farbigen Keramikscherben oder Natursteinen. Die Mitte der sechs Segmente bildet eine flache Schale, die als Springbrunnen oder Wasserschale gedacht ist. Die mit Erde gefüllten Durchbrüche in den Segmenten können mit Wildblumen bepflanzt werden, die Bienen, Schmetterlinge und andere Insekten anlocken. Die Wasserschale soll Insekten und Vögeln als Tränke dienen. In der vegetationsarmen Jahreszeit sorgt das Blütenornament der Bodengestaltung für eine freundliche Atmosphäre. Es tritt im Frühling und Sommer zunehmend hinter der Natur zurück, die sich aus ihm heraus entfaltet und es zu einer kleinen Oase werden lässt.

info:eu-repo/classification/ddc/620

ddc:620