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Supercritical gas cooling and condensation of refrigerant R410A at near-critical pressuresMitra, Biswajit 28 June 2005 (has links)
A comprehensive study of heat transfer and pressure drop of refrigerant R410A during condensation and supercritical cooling at near-critical pressures was conducted. Investigations were carried out at five nominal pressures: 0.8, 0.9, 1.0, 1.1 and 1.2xpcrit. The refrigerant was tested in commercially available horizontal smooth tubes of 6.2 and 9.4 mm I.D. Heat transfer coefficients were measured using a thermal amplification technique that measures heat duty accurately while also providing refrigerant heat transfer coefficients with low uncertainties. For condensation tests, local heat transfer coefficients and pressure drops were measured for the mass flux range 200 G 800 kg/m2-s in small quality increments over entire vapor-liquid region. For supercritical tests, local heat transfer coefficients and pressure drops were measured for the same mass flux range as in the condensation tests for temperatures ranging from 30 110oC.
Condensation heat transfer coefficients and pressure drops increased with quality and mass flux. The effect of reduced pressure on heat transfer is not very significant, while this effect is more pronounced on the pressure gradient. The flow regime transition criteria of Coleman and Garimella (2003) were used to initially designate the prevailing flow regimes for a given combination of mass flux and quality. The condensation data collected in the present study were primarily in the wavy and annular flow regimes. During supercritical cooling, the sharp variations in thermophysical properties in the vicinity of the critical temperature resulted in sharp peaks in the heat transfer coefficients and sudden jumps in the pressure drop. Based on the characteristics of the specific work of thermal expansion (contraction), the data from the supercritical tests were grouped into three regimes: liquid-like, pseudo-critical transition and gas-like regimes.
Flow regime-based heat transfer and pressure drop models were developed for both condensation and supercritical cooling. For condensation, the overall heat transfer model predicts 98% of the data within 15% while the overall pressure drop model predicts 87% of the data within 15%. For supercritical cooling, the heat transfer model predicted 88% of the data within 25% while the pressure gradient model predicts 84% of the data within 25%.
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Supercritical Gas Cooling and Near-Critical-Pressure Condensation of Refrigerant Blends in MicrochannelsAndresen, Ulf Christian 14 December 2006 (has links)
A study of heat transfer and pressure drop in zero ozone-depletion-potential (ODP) refrigerant blends in small diameter tubes was conducted. The azeotropic refrigerant blend R410A (equal parts of R32 and R125 by mass) has zero ODP and has properties similar to R22, and is therefore of interest for vapor compression cycles in high-temperature-lift space-conditioning and water heating applications. Smaller tubes lead to higher heat transfer coefficients and are better suited for high operating pressures. Heat transfer coefficients and pressure drops for R410A were determined experimentally during condensation across the entire vapor-liquid dome at 0.8, 0.9xPcritical and gas cooling at 1.0, 1.1, 1.2xPcritical in three different round tubes (D = 3.05, 1.52, 0.76 mm) over a mass flux range of 200 < G < 800 kg/m2-s. A thermal amplification technique was used to accurately determine the heat duty for condensation in small quality increments or supercritical cooling across small temperature changes while ensuring low uncertainties in the refrigerant heat transfer coefficients. The data from this study were used in conjunction with data obtained under similar operating conditions for refrigerants R404A and R410A in tubes of diameter 6.22 and 9.40 mm to develop models to predict heat transfer and pressure drop in tubes with diameters ranging from 0.76 to 9.40 mm during condensation. Similarly, in the supercritical states, heat transfer and pressure drop models were developed to account for the sharp variations in the thermophysical properties near the critical point. The physical understanding and models resulting from this investigation provide the information necessary for designing and optimizing new components that utilize R410A for air-conditioning and heat pumping applications.
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