Visualizing Load Path in Perforated Shear Walls

Chen, Ying Chih

19 March 2018

Shear walls are the primary lateral load resisting elements in bearing wall systems used in masonry construction. Horizontal loads due to wind or earthquake are transferred to vertical walls by diaphragms that are rigid such as concrete floor slabs or flexible such as wood floors. With rigid diaphragms, loads are apportioned to the supporting walls based on their relative rigidity. Walls with openings accommodating doors and windows (“perforated walls”) have reduced rigidity that can be determined using available hand calculation methods. These methods primarily focus on analysis procedures, not on the visualization of the load path that is critically important in structural engineering practice. The analogy of springs in series or parallel is used to determine the equivalent stiffness of elastic systems in structural dynamics. This thesis uses this analogy to develop a method that can help visualize load flow in perforated shear walls connected to rigid diaphragms. Rigidities are calculated using existing methods and combined as springs in series or parallel to represent a perforated wall. Loads taken by the wall segments correspond to the electrical current flowing through this imaginary “circuit”. To help visualize the load path, the line drawing representation of springs in series or parallel and the applied lateral load are deliberately oriented in the vertical direction. The application of the analogy is illustrated by several numerical examples of varying complexity taken from text books. Finite element solutions are included in the comparisons to provide a measure of the relative accuracy of hand calculation methods. The analogy can be extended to refine existing hand calculation methods though this increases computational effort. It improves accuracy but only for cases where the aspect ratio of the wall segments is such that shear effects are dominant.

force distribution

force flow

openings

refined method

rigidity

Engineering

Simulation of the Effect of Deck Cracking on the Behavior of the Prestressing Force in a Single Span Prestressed Concrete Girder

Vadlamani, Soumya

07 November 2017

No description available.

Civil Engineering

Differential Shrinkage

Cracking

Prestress Gain

Refined Method

Camber

Creep

A refined sampling procedure for genealogical control

Bickel, Balthasar

02 May 2024

Typological distributions are the combined result of universal structural principles, areal diffusion, and shared descent. The core concern of quantitative typology is to disentangle and to identify these various factors.While areal and structural factors can be tested against each other in standard multivariate designs based on sample stratification, genealogical factors cannot be handled by sample stratification since about one third of all proven families (the strata needed) are isolates, i.e. count only one member. In response, typologists have since long sought to control for genealogical relations during sampling rather than during statistical testing. But available methods suffer from a number of drawbacks. Most importantly, they are not sensitive to the fact that different typological variable have different degrees of stability (genealogical dependence) within families, and that this again varies from family to family.This article proposes a refined method for genealogical control during sampling, which is based on DRYER’s (1989) proposals but is sensitive to actual distributions within genealogical units at each taxonomic level.

info:eu-repo/classification/ddc/400

ddc:400