Experimental Study of a Bubble Mode Absorption with an Inner Vapor Distributor in a Plate Heat Exchanger-Type Absorber with NH3-LiNO3

Experimental Study of a Bubble Mode Absorption with an Inner Vapor Distributor in a Plate Heat Exchanger-Type Absorber with NH3-LiNO3

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Absorption systems are a sustainable solution as solar driven air conditioning devices in places chicago cubs earrings with warm climatic conditions, however, the reliability of these systems must be improved.The absorbing component has a significant effect on the cycle performance, as this process is complex and needs efficient heat exchangers.This paper presents an experimental study of a bubble mode absorption in a plate heat exchanger (PHE)-type absorber with NH3-LiNO3 using a vapor distributor in order to increase the mass transfer at solar cooling operating conditions.

The vapor distributor had a diameter of 0.005 m with five perforations distributed uniformly along the tube.Experiments were carried out using a corrugated plate heat exchanger model NB51, with three channels, where the ammonia vapor was injected in a bubble mode into the solution in the central channel.

The range of solution concentrations and mass flow rates of the dilute solution were from 35 to 50% weight and 11.69 to 35.46 × 10−3 kg·s−1, respectively.

The mass flow rate of ammonia vapor was from 0.79 to 4.92 × 10−3 here kg·s−1 and the mass flow rate of cooling water was fixed at 0.

31 kg·s−1.The results achieved for the absorbed flux was 0.015 to 0.

024 kg m−2·s−1 and the values obtained for the mass transfer coefficient were in the order of 0.036 to 0.059 m·s−1.

The solution heat transfer coefficient values were obtained from 0.9 to 1.8 kW·m−2·K−1 under transition conditions and from 0.

96 to 3.16 kW·m−2·K−1 at turbulent conditions.Nusselt number correlations were obtained based on experimental data during the absorption process with the NH3-LiNO3 working pair.