Plastic heat exchangers feature some unique characteristics such as light weight, easier fabrication, ability to resist chemical attack, low cost and longevity. For dehumidification using adsorption, plastic heat exchangers are commonly employed to dehumidify the moisture air regenerated from the heater. In practice, the processed cold air is first used to cool the hot moisture air. As a consequence, the condensation heat transfer performance of the moisture air becomes the bottleneck of plastic plate heat exchangers. The existing plastic heat exchanger for this heat recovery take the form as plate type. Therefore, the present study propose a novel design to enhance the condensation heat transfer by using the tube bundle configuration. The condensation heat transfer performance of the moisture air for both conventional plate type and the proposed configuration are made and compared. The experiments had been conducted at 1 atm, and a dry bulb temperature of 55°C with a relative humidity of 100%. The effect of volumetric flow rate is also examined. The cold side temperatures ate maintained at a dry bulb temperature at 27°C and a relative humidity at 60% with various volumetric flow rate. The results show that the performance, in terms of heat flux (or heat transfer coefficient), of the bare plastic tube heat exchangers outperforms the plate heat exchangers. This is because addition augmentation splashing effects of during condensation for the proposed tube bundle design. For the pressure drops, the moisture air shows higher pressure drop as compared to dry air without condensation. The results show that the bare plastic tube heat exchangers can enhance the heat transfer coefficient about 45%, the mass transfer coefficient about 34% and pressure drops by 26% subject to a same volumetric flowrate (when hot side is operated at 4.4 CFM and the cold side of is running at 42 CFM). Keywords: plastic heat exchangers, condensation heat transfer performances, volumetric flow rate, pressure drops.