Recent Trends in Civil Engineering & Technology

Wind is a phenomenon of great complexity because of the many flow situations arising from the interaction of wind with structures. Wind is of the most significant forces of nature that must be considered in design of buildings. The characteristics of wind-induced loads on buildings continuously vary in temporal and spatial dimensions. Adequate design of buildings depends on the success in predicting the actual effects of turbulent wind forces to account for the most critical design scenarios which may occur during a certain design period. Under the action of lateral load, a tall building can subjected to lateral or torsional deflection. Due to this lateral stiffness is a major criterion in the design of high rise building. From the past studies, it is found that to resist the lateral force, bracing system in a frame model is highly economical and efficient method. In this thesis, study is carried out to investigate the behaviour of building under wind load A G+17 frame model having RCC beams and columns of plan area 20m X 20m and first storey height is 4.75m and remaining storey’s height is 3.25m, is subjected to wind speed of 47m/s. And the same model is reinforced with X-bracing system at each corner of the building with an angle of size ISA 200X200X25mm.STAAD PRO software is used to analyze the building model subjected to wind load. The response study includes axial force, moment about both axes and displacement under various wind incidence angle. Behaviour of frame with and without bracings is also compared. The purpose of study is to evaluate the position of tall buildings with square shapes under wind loads got from experimental measurements. The linear static method is used to analyze buildings using STAAD.PRO software. For various wind incidents the response of building frame is obtained with angles of 0 degree, 30 degree, 60 degree under isolated conditions. Building of square shaped is considered for wind response analysis. A G+17 storied building of plan area 20mX20m and height 60 m is modelled using STAAD.PRO software. Building frame is consisting of R.C.C beams, columns and slab. Table gives the details of element and building dimensions

Z.A. Siddiqi, Rashid Hameed, Usman Akmal. “Comparison of Different Bracing Systems for Tall buildings, Pak. J. Engg. & Appl. Sci. Vol. 14, Jan., 2014(p.17-26).

Himanshu Gaur , Ravindra Kumar Goliya, “Correlating Stiffness and Shear Lag Behavior with Brace Configuration of Tall Truss Tube Buildings”

Narasimha Murthy K, Darshan SK, Karthik AS, Santosh R, Shiva Kumar KS, “Effective Study of Bracing Systems for Irregular Tall Steel Structures.

G Navya , Pankaj Agarwal, “Seismic Retrofitting of Structures by Steel Bracings”

Abdul karim, Pankaj Agarwal., “A study on Outrigger System in a Tall R.C Structures Using Steel Bracing”

Lekshmi Soman, Sreedevi Lekshmi, “Comparative Study of Outrigger System with Braced Frame Core and Shear Core in High Rise Building.”

Adithya. M , Swathi rani K.S , Shruthi H K , Dr. Ramesh B.R , “Study On Effective Bracing Systems for High Rise Steel Structures” , SSRG International Journal of Civil Engineering, ISSN: 2348 – 8352, volume 2, Issue 2, February 2015, PP 19-22.

IS: 875 (Part 1,2,3)-1987, “Code of practice for design loads (other than earthquake) for building and structures, part 3 wind loads” 6th reprint, November 1998 Bureau of Indian Standards, New Delhi, India.