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Date of Award
Spring 2025
Document Type
Masters Thesis
Department or Program Affiliation
Environmental Studies
Degree Name
Master of Arts (MA)
Department
Environmental Studies
First Advisor
Hollenhorst, Steven J.
Second Advisor
Barnhart, Charles
Third Advisor
Sheikh, Imran
Abstract
This study examined two replacement options for the district heating system at Western Washington University based on CO2e emissions savings and system feasibility. Life cycle assessment was used to compare a nodal air source heat pump system with supplemental geo-exchange and a nodal air source heat pump system with water preheated from waste heat sources. The systems were also compared at their designed water temperature of 120, and at a temperature of 180, with natural gas used to boost the water temperature. This work adds to the body of knowledge for universities seeking to replace aging steam-based heating system. It provides results about the feasibility of incrementally upgrading heating systems and using geothermal and waste heat sources at a university scale. The EcoInvent 3.11 systems library, the Recipe Endpoint (H/A), and IPCC 2021 GTP 100 V1.03 methods were used for the LCA. I found that in both the geothermal and waste heat cases, the high temperature scenarios resulted in high emissions of 554kton CO2e and 377kton CO2e, respectively, over the 50-year project lifetime. The Business-As-Usual case, which assumes WWU continues to use the natural-gas-powered steam plant, produced 468kton CO2e over 50 years. For low-temperature scenarios, the geothermal system produced 240kton CO2e over the project lifetime, and the waste heat system produced 120kton CO2e. The emissions for the construction of all scenarios were under 14kton CO2e. These results show that the high-temperature scenarios are not appropriate options due to their high emissions of 118% of the BAU emissions for the geothermal scenario, and 82% of the BAU emissions for the Port scenario. The results also show the Port low-temperature scenario has the lowest emissions of all use scenarios, 120kton CO2e, and is therefore the recommended option for WWU.
Type
Text
Keywords
life cycle analysis, district heating, heat pumps, geo-exchange, university, low-temperature hot water, high-temperature hot water, GHG emissions
Publisher
Western Washington University
OCLC Number
1523220628
Subjects – Names (LCNAF)
Western Washington University
Subject – LCSH
Heating from central stations--Washington (State)--Bellingham; Ground source heat pump systems--Washington (State)--Bellingham; Heat recovery; Replacement of industrial equipment--Washington (State)--Bellingham; Life cycle costing--Washington (State)--Bellingham; Carbon dioxide mitigation--Washington (State)--Bellingham; Natural gas--Environmental aspects--Washington (State)--Bellingham
Geographic Coverage
Bellingham (Wash.)
Format
application/pdf
Genre/Form
masters theses
Language
English
Rights
Copying of this document in whole or in part is allowable only for scholarly purposes. It is understood, however, that any copying or publication of this document for commercial purposes, or for financial gain, shall not be allowed without the author’s written permission.
Rights Statement
http://rightsstatements.org/vocab/CNE/1.0/
Recommended Citation
Deitering, Juniper, "A Life Cycle Analysis of District Heating Options for Western Washington University" (2025). WWU Graduate School Collection. 1395.
https://cedar.wwu.edu/wwuet/1395
An excel file of the calculations that went into making the SimaPro models. Additionally listed in the thesis as Appendix A.