SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4384501676> ?p ?o ?g. }

Showing items 1 to 100 of ±115 with 100 items per page.

W4384501676 endingPage "102022" @default.
W4384501676 startingPage "102022" @default.
W4384501676 abstract "In the intensive care unit of hospitals, retaining the relative humidity at a comfortable level, removing air-borne pollutants or microbial bacteria, filtering ambient air, and eradicating the condensed water vapor are crucial. Therefore, a desiccant coated energy exchanger (DCEE) is designed for fulfilling this purpose. In the present investigation, a quick prediction of the exit parameters of desiccant coated energy exchanger is made using three data-driven models: artificial neural network artificial intelligence tool (ANN-AI), k-nearest neighbors machine learning tool (KNN-ML), and principal component analysis (PCA). From the model validation and error analysis, it has been found that the ANN-AI tool predicts the exit parameters with the least error. The advantages of ANN-AI tool are its exceptional learning capability and fast output prediction. Artificial neural networks are adaptive and flexible. ANN obtains information from their surroundings by adapting to input and output parameters, thus solving complicated problems which are challenging to handle. The design parameters chosen for designing the desiccant coated energy exchanger are tube diameter, fin depth, thickness of coated desiccant, and flow channel length. Silica gel is used as a desiccant-coated material. Thermal effectiveness and moisture effectiveness are chosen as performance parameters, inlet air humidity ratio, inlet air temperature, inlet cooling water temperature, liquid to air mass flow rate, and cycle time are chosen as inlet parameters and outlet air temperature, outlet cooling water temperature, outlet air humidity ratio as the exit parameters. Further, optimal and design operating parameters of the desiccant coated energy exchanger is predicted for a particular operating/design range utilizing the ANN–AI tool. Moreover, a case study has been carried out first by integrating a desiccant coated energy exchanger with a M−cooler and second by integrating a desiccant coated energy exchanger with a solar heater to assess the air conditioning and drying performance. The findings of the case study reveal that inlet cooling water temperature and inlet air temperature are the most significant parameters for the M−cooler and solar heater, which produce the lowest/largest temperature at the M−cooler/solar heater outlet, respectively." @default.
W4384501676 created "2023-07-18" @default.
W4384501676 creator A5000490244 @default.
W4384501676 creator A5003479098 @default.
W4384501676 date "2023-08-01" @default.
W4384501676 modified "2023-10-02" @default.
W4384501676 title "Performance potentiality analysis of desiccant coated energy exchanger for M−cooler based air conditioning and solar driven drying systems – A case study" @default.
W4384501676 cites W1052683414 @default.
W4384501676 cites W1973325732 @default.
W4384501676 cites W2035142162 @default.
W4384501676 cites W2055681464 @default.
W4384501676 cites W2126779618 @default.
W4384501676 cites W2166527890 @default.
W4384501676 cites W2236522545 @default.
W4384501676 cites W2284930041 @default.
W4384501676 cites W2402836230 @default.
W4384501676 cites W2602139871 @default.
W4384501676 cites W2753953804 @default.
W4384501676 cites W2777350292 @default.
W4384501676 cites W2887649907 @default.
W4384501676 cites W2892792031 @default.
W4384501676 cites W2912387255 @default.
W4384501676 cites W2942865205 @default.
W4384501676 cites W2945056141 @default.
W4384501676 cites W2990888838 @default.
W4384501676 cites W2995983610 @default.
W4384501676 cites W3000709389 @default.
W4384501676 cites W3004105733 @default.
W4384501676 cites W3032773305 @default.
W4384501676 cites W3037534559 @default.
W4384501676 cites W3092191117 @default.
W4384501676 cites W3105304668 @default.
W4384501676 cites W3132133310 @default.
W4384501676 cites W3135952880 @default.
W4384501676 cites W3138132653 @default.
W4384501676 cites W3153311420 @default.
W4384501676 cites W3156169081 @default.
W4384501676 cites W3194216807 @default.
W4384501676 cites W3210911070 @default.
W4384501676 cites W3211036174 @default.
W4384501676 cites W4200319775 @default.
W4384501676 cites W4213025181 @default.
W4384501676 cites W4224224864 @default.
W4384501676 cites W4286252289 @default.
W4384501676 cites W4293581585 @default.
W4384501676 cites W4309990806 @default.
W4384501676 cites W4310243220 @default.
W4384501676 cites W4310712185 @default.
W4384501676 cites W585309665 @default.
W4384501676 doi "https://doi.org/10.1016/j.tsep.2023.102022" @default.
W4384501676 hasPublicationYear "2023" @default.
W4384501676 type Work @default.
W4384501676 citedByCount "1" @default.
W4384501676 countsByYear W43845016762023 @default.
W4384501676 crossrefType "journal-article" @default.
W4384501676 hasAuthorship W4384501676A5000490244 @default.
W4384501676 hasAuthorship W4384501676A5003479098 @default.
W4384501676 hasConcept C103742991 @default.
W4384501676 hasConcept C107706546 @default.
W4384501676 hasConcept C121332964 @default.
W4384501676 hasConcept C127413603 @default.
W4384501676 hasConcept C151420433 @default.
W4384501676 hasConcept C153294291 @default.
W4384501676 hasConcept C154945302 @default.
W4384501676 hasConcept C158960510 @default.
W4384501676 hasConcept C159985019 @default.
W4384501676 hasConcept C172120300 @default.
W4384501676 hasConcept C192562407 @default.
W4384501676 hasConcept C201289731 @default.
W4384501676 hasConcept C21880701 @default.
W4384501676 hasConcept C37819138 @default.
W4384501676 hasConcept C39432304 @default.
W4384501676 hasConcept C41008148 @default.
W4384501676 hasConcept C50644808 @default.
W4384501676 hasConcept C57879066 @default.
W4384501676 hasConcept C78519656 @default.
W4384501676 hasConceptScore W4384501676C103742991 @default.
W4384501676 hasConceptScore W4384501676C107706546 @default.
W4384501676 hasConceptScore W4384501676C121332964 @default.
W4384501676 hasConceptScore W4384501676C127413603 @default.
W4384501676 hasConceptScore W4384501676C151420433 @default.
W4384501676 hasConceptScore W4384501676C153294291 @default.
W4384501676 hasConceptScore W4384501676C154945302 @default.
W4384501676 hasConceptScore W4384501676C158960510 @default.
W4384501676 hasConceptScore W4384501676C159985019 @default.
W4384501676 hasConceptScore W4384501676C172120300 @default.
W4384501676 hasConceptScore W4384501676C192562407 @default.
W4384501676 hasConceptScore W4384501676C201289731 @default.
W4384501676 hasConceptScore W4384501676C21880701 @default.
W4384501676 hasConceptScore W4384501676C37819138 @default.
W4384501676 hasConceptScore W4384501676C39432304 @default.
W4384501676 hasConceptScore W4384501676C41008148 @default.
W4384501676 hasConceptScore W4384501676C50644808 @default.
W4384501676 hasConceptScore W4384501676C57879066 @default.
W4384501676 hasConceptScore W4384501676C78519656 @default.
W4384501676 hasFunder F4320325377 @default.
W4384501676 hasLocation W43845016761 @default.
W4384501676 hasOpenAccess W4384501676 @default.