Author

Mark Hurley

ORCID Identifier(s)

0000-0003-1883-6589

Graduation Semester and Year

2019

Language

English

Document Type

Thesis

Degree Name

Master of Science in Civil Engineering

Department

Civil Engineering

First Advisor

Xinbao Yu

Abstract

Geothermal energy has always been available as a renewable thermal reserve, however, only recently has it been unlocked as a potential source of energy to de-ice bridges and roadways. The ability to efficiently extract the geothermal reserves has been accomplished with the advent of new technology. Each progressing year, the refinement of technology has led to a reduction in the input required to achieve a desired output. For the case of bridge de-icing, the extracted input of thermal energy must exceed the required demands to permit de-icing. The conventional approach to de-icing (using chemicals, salt, and sand) works as a mediator of the freeing point to melt ice, however, there is absence of thermal energy. Therefore, various methods have been devised to generate heat using different sources of energy with the intended goal of efficient de-icing. The focus for this thesis is to experimentally simulate the derivation of geothermal energy via a hydronic loop de-icing system. A small-scale bridge slab was subjected to multiple winter scenarios in a controlled setting to obtain a prediction of the thermal reserves required to permit de-icing. An additional slab was placed in an outdoor environment to test the performance of the system under cyclic conditions over the span of a winter period. The vertical and lateral thermal distribution across the slab was determined to gauge the temperature variation in reference to the pipe geometry. The thermal minimum was also determined to obtain the maximum heat input requirement. The negative influence of sustained wind was studied to attain a relationship of thermal demands as a function of wind magnitude. A thermal rebound study is provided to determine the recovery rate of thermal energy in respect to a negative incremental change in wind magnitude. By compiling the steady-state response of the slab for a wide range of winter scenarios and creating an error bound estimate, the thermal demands could be predicted with a higher degree of precision. The final aim is to formulate a design criterion to estimate the required inlet temperature to achieve efficient ice removal across the entire slab area.

Keywords

Geothermal, Bridge de-icing, Thermal rebound, Heat transfer, Hydronic loops

Disciplines

Civil and Environmental Engineering | Civil Engineering | Engineering

Comments

Degree granted by The University of Texas at Arlington

28106-2.zip (8263 kB)

Share

COinS
 
 

To view the content in your browser, please download Adobe Reader or, alternately,
you may Download the file to your hard drive.

NOTE: The latest versions of Adobe Reader do not support viewing PDF files within Firefox on Mac OS and if you are using a modern (Intel) Mac, there is no official plugin for viewing PDF files within the browser window.