The bellows structure has two characteristics of enhanced heat transfer compared to a normal straight pipe with the same outside diameter.
(i) The increased area of the bellows structure.
② The heat transfer coefficient increases due to the thinning of the condensate film. The bellows structure plays a major role in enhancing heat transfer.

At this time, the flow pattern of the liquid film on the top and bottom surfaces of the corrugation is similar, and the liquid film flows from the crest to the bottom of the valley along the corrugated surface, which makes the liquid film in the crest area thinner and greatly reduces the thermal resistance of the heat flow through the surface of the crest area and strengthens the heat transfer. The condensation in the crest area is film-like, but the heat transfer coefficient is within the range of the bead-like heat transfer coefficient. The bottom of the trough area collects the entire corrugated surface condensate, and the effect of gravity is much greater than the effect of surface tension. Under the control of gravity, the condensate flows downward along the circumferential wall, and the heat flow through the bottom of the trough is small. Under the joint action of surface tension and gravity, the condensate film flow pattern is more complex and difficult to judge accurately. The flow pattern of the liquid film is usually simplified into two categories: gravity-controlled and surface tension-controlled condensation.
The instability problem of metal hose is a very strong geometric nonlinear problem, with a very complex load a displacement path. Metal hose withstand excessive internal pressure will produce warpage, reducing its load-bearing capacity, displacement absorption capacity and fatigue life, so that the metal hose further warpage, so the cycle, will make the metal hose in the case of bearing pressure is not high destabilization damage, resulting in the failure of the entire bellows structure.
