<p dir="ltr">Building cooling and ventilation account for nearly 10% of the global electricity consumption. In fact, a recent study even showed that, globally, dehumidification consumes more energy than sensible cooling. One high-efficiency dehumidification technology is selective membrane dehumidification. Selective membranes allow water vapor transport but block air transport. There are two overarching gaps in the literature that are addressed in this dissertation: (1) vacuum membrane dehumidification (VMD) has been rigidly defined as an isothermal process and (2) literature on one of the most efficient VMD system designs, which I will refer to as the “dual module humidity pump,” is limited to ideal thermodynamic modeling (no experimental demonstration or practical system modeling in the current literature).</p><p dir="ltr">This work presents a novel system concept, referred to as the “Active Membrane Energy Exchanger” (AMX), which specifically couples VMD and air cooling into one process to provide the first non-isothermal VMD system concept. The present study provides a wholistic understanding of the benefits and limitations of the AMX approach through both thermodynamic system modeling and experimental protype development and demonstration.</p><p dir="ltr">System models developed in Engineering Equation Solver were used to compare the energy performance of the AMX to other HVAC technologies. These models showed that the AMX could achieve up to 25% annual cooling electricity savings in commercial buildings and up to 60% annual cooling electricity savings in 100% outdoor air applications. Experiments showed that combining cooling and dehumidification increased membrane permeance by up to 40% and increased dehumidification performance by 3-6%. Further demonstration showed the prototype could remove up to 45% of the humidity in the humid air flow but struggled to reject all of that vapor to the exhaust air (mass transfer imbalance). This discovery enabled a practical thermofluid model to estimate theoretical and practical COP limits, which were approximately 40 and 10, respectively. Additionally, a global sensitivity analysis on the new model showed that mechanical design is far more limiting to the performance than material design.</p><p dir="ltr">In summary, this dissertation develops and demonstrates a novel air conditioning technology, from system modeling to prototype demonstration. This work was funded and guided by industry partners, and the results of this dissertation are a major step towards real-world implementation.</p>
| Identifer | oai:union.ndltd.org:purdue.edu/oai:figshare.com:article/24665763 |
| Date | 30 November 2023 |
| Creators | Andrew J Fix (17482464) |
| Source Sets | Purdue University |
| Detected Language | English |
| Type | Text, Thesis |
| Rights | CC BY 4.0 |
| Relation | https://figshare.com/articles/thesis/COUPLING_ACTIVE_HEAT_EXCHANGE_AND_VACUUM_MEMBRANE-BASED_AIR_DEHUMIDIFICATION_FOR_HIGH-EFFICIENCY_AIR_CONDITIONING/24665763 |
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