Analysis of a Flat-Plate, Liquid-Desiccant, Dehumidifier and Regenerator

Mesquita, Lucio Cesar De Souza

14 January 2008

A numerical model for isothermal and non-isothermal flat-plate liquid-desiccant dehumidifiers and regenerators was developed and implemented. The two-dimensional model takes into account the desiccant, water and air flow streams. A parametric analysis was performed to evaluate the influence of some of the most important operational parameters on mass transfer performance, such as flow configuration, water mass flow rate and inlet temperature, and desiccant mass flow rate. The results indicate that the water temperature and mass flow rate have a strong effect on the performance of the dehumidifier and regenerator, with the isothermal wall case acting as an upper limiting case. Increasing the desiccant mass flow rate improves the water transfer performance, but the improvement is asymptotic with mass flow rate. An experimental rig with a single channel prototype was also built and tests were run for 18 different cases, with varying water mass flow rate, desiccant mass flow rate and flow configuration. The results show trends similar to those observed in the numerical results. However, the discrepancies between the numerical and experimental results are larger than the estimated experimental uncertainty at a 95% confidence level. There is some indication that poor desiccant wetting of the channel walls was partially responsible for the discrepancies. / Thesis (Ph.D, Mechanical and Materials Engineering) -- Queen's University, 2007-12-31 22:12:39.184

liquid desiccant

solar energy

air-conditioning

dehumidification

Evaluation of an Indirect Solar Assisted Heat Pump Water Heater in the Canadian Environment

ELLIOTT, BRYN DAVIS

06 January 2012

Solar Domestic Hot Water systems and air-source heat pumps offer the potential for energy savings in residential hot water production, however their performance is limited in cold climates, where the low ambient temperature reduces the collector efficiency or the heat pump coefficient of performance. Combining these systems into a Solar-Assisted Heat Pump can alleviate these limitations by reducing the required collector temperature and by providing an increased heat pump evaporator temperature. This study is a continuation of the development of an Indirect Solar-Assisted Heat Pump undertaken at the Queen’s University Solar Calorimetry Laboratory. Previously, a numerical study compared its performance to existing technology, and based upon this feasibility analysis, a prototype was constructed for controlled laboratory tests using simulated solar input. In the current study, the prototype was modified to include a novel hybrid collector such that its performance under actual weather conditions throughout the year could be assessed. On sunny days, the system experienced daily averaged collector efficiencies between 0.47 and 0.88, depending on the flow rate and season. Averaged heat pump coefficients of performance of 2.54 to 3.13 were observed. Overcast days experienced reduced coefficients of performance, between 2.24 and 2.44. However, on overcast days, upwards of 76% of the collected energy gain was from convection with the surroundings. Based upon these experimental results, a model for the hybrid collector was developed. Annual simulations of the system were conducted to compare the performance of the solar heat pump system when fitted with the hybrid collector relative to cases with more conventional glazed and unglazed collectors commonly used in solar thermal systems. Results were produced for three Canadian cities: Toronto, Vancouver and Winnipeg. The heat pump with the hybrid collector outperformed the other collectors in the Toronto climate, with a free energy ratio of 0.548. Adding a thermally controlled valve to the hybrid collector was proposed to further increase the annual free energy ratio, and was shown to perform best in all three cities, with free energy ratios of 0.558, 0.576 and 0.559 for Toronto, Vancouver and Winnipeg, respectively. It is proposed that additional improvements could be achieved by allowing the collectors to deliver heat directly to the storage tank, by circumventing the heat pump if the conditions were favorable. / Thesis (Master, Mechanical and Materials Engineering) -- Queen's University, 2012-01-06 13:44:41.77

Domestic Hot Water

Heat Pump

Solar Energy

The study of a double-effect basin type solar still.

Lantagne, Michel.

January 1971

No description available.

Solar energy

Theoretical and experimental analysis for optimizing the performance of a SLPP

Papaioannou, Ioannis.

January 1985

No description available.

Reciprocating pumps.

Solar energy.

Computer simulation.

Improved understanding and control of the properties of PECVD silicon nitride and its applications in multicrystalline silicon solar cells

Cai, Li

05 1900

No description available.

Photovoltaic cells

Silicones

Solar energy

Solar cells

An investigation of the relationship between beam and global irradiation with the development of numerical solar radiation models

Balaras, Constantinos Agelou

08 1900

No description available.

Global radiation

Solar radiation

Solar energy

A method for sizing flat plate solar collectors for space and hot water heating

Sicner, Karen Maffitt

08 1900

No description available.

Solar energy

Architecture and energy conservation

Solar collectors

Solar food drying in Zambia

Kwendakwema, Nicholas John.

January 1983

No description available.

Food -- Drying.

Vegetables -- Drying.

Solar energy -- Zambia.

Performance characteristics and computer modelling of a solar liquid piston pump

Brew-Hammond, J. P. Abeeku.

January 1984

No description available.

Reciprocating pumps.

Solar energy.

Computer simulation.

Photoelectrochemical and photocatalytic investigation of semiconducting iron oxide for solar energy conversion /

Strasik, Michael,

January 1988

Thesis (Ph. D.)--Oregon Graduate Center, 1988.