Experimental Characterization of Flow Induced Vibration in Turbulent Pipe Flow

Thompson, Andrew S.

12 August 2009

This thesis presents results of an experimental investigation that characterizes the wall vibration of a pipe with turbulent flow passing through it. Specifically, experiments were conducted using a water flow loop to address three general phenomena. The topics of investigation were: 1) How does the pipe wall vibration depend on the average flow speed, pipe diameter, and pipe thickness for an unsupported pipe? 2) How does the behavior change if the pipe is clamp supported at various clamping lengths? 3) What influence does turbulence generation caused by holed baffle plates exert on the pipe response? A single pipe material (PVC) was used with a range of internal diameters from 5.08 cm to 10.16 cm and diameter to thickness ratios ranging from 8.90 to 16.94. The average flow speed that the experiments were conducted at ranged from 0 to 11.5 m/s. Pipe vibrations were characterized by accelerometers mounted on the pipe wall at several locations along the pipe length. Rms values of the pipe wall acceleration and velocity time series were measured at various flow speeds. Power spectral densities of the accelerometer data were computed and analyzed. Concurrent wall pressure fluctuation measurements were also obtained. The results show that for a fully developed turbulent flow, the rms of the wall pressure fluctuations is proportional to the rms of the wall acceleration and each scale nominally as the square of the average fluid velocity. Also, the rms of the pipe wall acceleration increases with decreasing pipe wall thickness. When changes were made in the pipe support length, it was observed that, in general, pipe support length exercises little influence on the pipe wall acceleration. The influence of pipe support length on the pipe wall velocity is much more pronounced. A non-dimensional parameter describing the pipe wall acceleration is defined and its dependence on relevant independent non-dimensional parameters is presented. Turbulence was induced using baffle plates with various sizes (2.54 cm to 0.159 cm) and numbers of holes drilled through them to provide a constant through area of 35.48 cm2 for each plate. Cavitation exists at high speeds for the largest holed baffle plates and this significantly increases the rms of the pipe wall acceleration. As the baffle plate hole size decreases, vibration levels were observed to return to levels that were observed when no baffle plate was employed. Power spectral densities of the accelerometer data from each baffle plate scenario were also computed and analyzed.

pipe flow

turbulence

vibrations

flow rate

non-dimensionalization

baffle plates

Mechanical Engineering

Non-Dimensional Modeling of the Effects of Weld Parameters on Peak Temperature and Cooling Rate in Friction Stir Welding

Stringham, Bryan Jay

01 April 2017

Methods for predicting weld properties based on welding parameters are needed in friction stir welding (FSW). FSW is a joining process in which the resulting properties depend on the thermal cycle of the weld. Buckingham's Pi theorem and heat transfer analysis was used to identify dimensionless parameters relevant to the FSW process. Experimental data from Al 7075 and HSLA-65 on five different backing plate materials and a wide range of travel speeds and weld powers was used to create a dimensionless, empirical model relating critical weld parameters to the peak temperature rise and cooling rate of the weld. The models created have R-squared values greater than 0.99 for both dimensionless peak temperature rise and cooling rate correlations. The model can be used to identify weld parameters needed to produce a desired peak temperature rise or cooling rate. The model can also be used to explore the relative effects of welding parameters on the weld thermal response.

Friction Stir Welding

Dimensional Analysis

Non-dimensionalization

Thermal Response Modeling

Peak Temperature

Cooling Rate

Rosenthal equation

Experimental Data

Mechanical Engineering

The Objective/Subjective Nature of Affordance Use in Digital Environments: Building a Tailored Climate Change Adaptation Website for the Colombian Coffee Sector

Jessica Eise (8801109)

06 May 2020

<p>This dissertation extends our knowledge of digital affordances in communicating complex scientific information by building and testing a climate change adaptation website for the Colombian coffee sector, <a href="http://www.climaycafe.com/">www.climaycafe.com</a>. This project offers both a practical component (scholarship of engagement) and theoretical component (extension of our understanding of the objective/subjective nature of affordances). Practically, it seeks to create a collaborative and tailored science communication solution for improved information access to support climate change adaptation. Theoretically, it extends our understanding of affordances in a digital environment through a qualitative assessment, specifically how occupational identity influences the subjective nature of affordances. Data is gathered through an iterative qualitative assessment of users’ interpretation of the perceived affordances on the website. The results demonstrate that occupational identity has an influence on perceived digital affordances, particularly influenced by (1) Perceived Social Status of Occupation, (2) Perception of Value Based on Occupational Demands, (3) Occupational Influence on Perceived Reliability and (4) Usability Preferences Based on Occupation. We additionally found that as creators we can set general goals for digital tools and achieve general success in obtaining them, but ultimately the users will dictate their needs within this broader framework. Lastly, there is a self-identified need for more practical knowledge and information access for coffee farmers in these regions of Colombia around climate change adaptation.</p>

Digital Humanities

Environmental Humanities

Environmental Education and Extension

Communication Studies

digital affordances

science communication

environmental communication

media technology

climate change adaptation

coffee producers

colombian coffee

engaged scholarship

climate change

dimensionalization