What are the factors affecting condensation heat transfer

　　Due to the complexity of condensation heat transfer, the change of many factors will have an impact on condensation heat transfer. The main influencing factors of condensation heat transfer include non-condensing gas, gas flow rate, air flow direction, liquid film Reynolds number and tube row number.

　　1. No condensation

　　The presence of non-condensing gas will have a very adverse effect on condensation heat transfer, such as 1% of water vapor (mass fraction) of air will reduce the condensation heat transfer coefficient by 60%. Because as the vapor condenses, the concentration of non-condensable gas at the interface will continue to increase, and the vapor must diffuse through the non-condensable gas layer accumulated near the interface before reaching the liquid film surface to condense, increasing the heat transfer resistance; The decrease of vapor partial pressure causes the corresponding saturation temperature to decrease, thus reducing the driving force of condensing temperature difference. Therefore, in the design of condenser, it is very important to avoid the accumulation of non-condensing gas.

　　2. Gas flow rate

　　The effect of gas flow rate on condensation heat transfer is negligible at low flow rate, but the viscous stress on liquid film surface is obvious at high flow rate. In the flow rate range of industrial operation, the effect of gas flow rate on the heat transfer coefficient of condensation is very small.

　　3. Air flow direction

　　If the direction of air flow is consistent with the direction of liquid film flow, thin liquid film will be drawn, which is beneficial to condensation heat transfer; On the contrary, it will thicken the liquid film and reduce the heat transfer efficiency of condensation. For example, a liquid film flows from top to bottom when the gas flow is consistent with it. Because the gas film has stirring effect, it is favorable for heat transfer; On the contrary, if the gas flows from the bottom to the top, it will reduce the downward flow speed of the liquid film, and even bring the lower part of the condensate to the top, so that the thickness of the liquid film above will increase, which will reduce the average heat transfer coefficient value, so the gas is best to flow from top to bottom in the vertical condenser.

　　In addition, in the condenser, because of the relationship between the baffle, the gas flow is perpendicular to the pipe, so that because the shear effect of the gas on the condensate blows off the condensate, the actual average heat transfer coefficient value of the saturated gas condensation is slightly larger than the calculated value, so the gas flow should be perpendicular to the pipe as far as possible.

　　4. Liquid film Reynolds number

　　The condensation process in industry is mostly in the laminar flow region, where the relationship between the average heat transfer coefficient and Reynolds number (Re) is different from that of convective heat transfer without phase transition.

　　When Re<2100, that is, in the laminar flow area, the average liquid film thickness also increases with the increase of condensation amount, which makes the average heat transfer coefficient decrease with the increase of condensation amount, that is, the average heat transfer coefficient decreases with the increase of gas flow rate. The above situation is the opposite of a heat exchanger without phase change, so this relationship should be taken into account when designing the condenser. It should be emphasized here that the effect of increasing the amount of condensation on the average heat transfer coefficient and the effect of increasing the gas flow rate are two different concepts, and should not be confused.

　　5. Number of pipe rows

　　When the gas condenses outside the beam tube of the heat exchange tube, the condensate of the upper exhaust pipe will drop to the lower exhaust pipe, which will reduce the condensation heat transfer efficiency of the lower exhaust pipe. However, when the condensate drop falls, it will cause splashing and impact disturbance on the liquid film, which will strengthen the condensation heat transfer of the lower exhaust pipe. Therefore, comprehensive consideration should be taken in the design.

　　6. Influence of condenser arrangement

　　Shell and tube condensers have two kinds: vertical and horizontal. When the number of condensers is large, there are two kinds in series and parallel arrangement. Therefore, when selecting a model, you can directly choose a large or several small ones.