DESIGN AND THERMAL ANALYSIS ON CRYOGENIC PRESSURE VESSEL

Abstract

After a cryogenic liquid has been liquefied and purified to the desired level; it should then be put away and
transported. Cryogenic fluid storage-vessel and transfer line design has progressed rapidly as a result of the growing use
of cryogenic liquids in many areas of engineering and science. The development of the Dewar vessel represented such an
improvement in cryogenic fluid storage vessels that it could be classed as a “break-through” in container design.
Cryogenic Pressure vessels are weight vessels are utilized for capacity cryogenic fluids with least warmth inspill into the vessel from the outside beyond what many would consider possible. The test of configuration is to utilize
such materials that don't lose their alluring properties at such a low temperature. Here the most extreme care is taken to
plan a capacity vessel fulfilling both mechanical and Thermal Properties. The outcomes will be contrasted with the
current vessel of industry. Glass epoxy can be utilized which will decrease warm exchange from conduction of Surge
plates which are bolster from external vessel to inward vessel. The glass epoxy significantly with stands the temperature.
They appear in these sectors as industrial compressed air receivers and domestic hot water storage tanks. Other
examples of pressure vessels are diving cylinders, recompression chambers, distillation towers, pressure reactors, etc.
The modeling is performed in Catia V5R20 and the thermal analysis is carried out in Ansys 15.0 workbench.