Water Vapor Adsorption-Desorption Behavior of Surfactant-Coated Starch Particles for Commercial Energy Wheels

Mohsen Shakouri, Easwaran N. Krishnan, Abdalla H. Karoyo, Leila Dehabadi, Lee D. Wilson, Carey J. Simonson

Research output: Contribution to journalArticlepeer-review

13 Scopus citations

Abstract

This study reports on the adsorption (dehumidification)-desorption (humidification) behavior of cetylpyridinium bromide (CPB) coated starch particles (SPs), denoted as SP-CPB, as a potential desiccant material for air-to-air energy exchangers. CPB is a cationic surfactant with antibacterial activity that can be used to modify the surface properties of SPs, especially at variable CPB loading levels (SP-CPB0.5, SP-CPB2.5, and SP-CPB5.0, where the numeric suffix represents the synthetic loading level of CPB in mM). The SP-CPB0.5 sample displayed optimal surface area and pore structure properties that was selected for water sorption isotherm studies at 25 °C. The CPB-coated SPs sample (SP-CPB0.5) showed an improved water vapor uptake capacity compared to unmodified starch (SPs) and other desiccant systems such as high amylose starch (HAS15) and silica gel (SG13). Single-step and cyclic water vapor sorption tests were conducted using a small-scale exchanger coated with SP-CPB0.5. The calculated latent effectiveness values obtained from direct measurements using cyclic tests (65.4 ± 2%) agree closely with the estimated latent effectiveness from single-step tests (64.6 ± 2%) at controlled operating conditions. Compared to HAS15- A nd SG13-coated exchangers, the SP-CPB0.5-coated exchanger performed much better at controlled operating conditions, along with improved longevity due to the CPB surface coating. The presence of CPB did not attenuate the uptake properties of native SPs. Latent effectiveness of SP-CPB0.5-coated exchanger was enhanced (5-30% higher) over that of the SG13-or HAS15-coated exchangers, according to the wheel angular speed. This study reports on a novel and sustainable SP-CPB0.5 material as a promising desiccant coating with tunable uptake and surface properties with potential utility in air-to-air energy exchangers for ventilation systems.

Original languageEnglish
Pages (from-to)14378-14389
Number of pages12
JournalACS Omega
Volume4
Issue number11
DOIs
StatePublished - Sep 10 2019
Externally publishedYes

Funding

The Government of Saskatchewan (Ministry of Agriculture), through the Agriculture Development Fund (Project No. 20160266), is gratefully acknowledged for supporting this research. Michael Oelck and Canadian Carnation BioProducts Inc. is acknowledged for provision of starch particles for this research.

FundersFunder number
Ministry of Agriculture - Saskatchewan20160266

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