Q_Goest said:You don't need to design your own bellows, they are readily available off the shelf. That includes short lengths made up with ends that can be bolted, screwed or welded into a piping system. If your intent is to figure out what lengths of these expansion joints are required to compensate for thermal contraction of the piping, that's covered by various piping codes which are unique to the country you live in.
Q_Goest said:There's always a reason for going to the expense of putting in an expansion joint. Generally, there are 2 reasons for installing such a joint, vibration and thermal contraction/expansion. I'm assuming your case is the latter since you're dealing with liquid nitrogen. It's not cheap to install these joints and it's not easy to determine exactly what type and length you need. In fact, if you can do away with them, you'll be much better off. But to get out of using them, the piping has to be flexible enough to prevent stresses in excess of what is allowed by the piping code for your country. Therefore, someone is going to have to do a piping stress analysis for your liquid nitrogen system and they'll need to accommodate thermal contraction of the piping, so an expansion joint is a common method. Today, most companies use a computer program to analyze stresses in piping, and that analysis is done in conformance with the applicable piping code for the country in question. For the US, that piping code will be ASME B31.3, but in other countries, other codes will apply.
You can't determine the type and location of the expansion joint yourself, you need someone that can provide the stress analysis per the applicable code for your country. Once you have requirements from that person, you can go off and determine what suppliers can provide that expansion joint.
Sorry if that sounds like I'm avoiding your question, but I have to assume this is an industrial application, not a college project.
The piping code applicable to this design will provide guidance on the piping stress analysis. It can be done by hand or by computer.skyqwerty said:appreciate what u have told me... can i ask something more? how is a pipe stress analysis like? can be done manually? calculations?
The size and shape of a bellows for cryogenic pipes depends on several factors, such as the pressure and temperature of the fluid, the pipe material, and the expected movement and flexibility needed. It is recommended to consult with a cryogenic piping expert or use specialized software to accurately determine the appropriate bellows size and shape for your specific application.
The most commonly used materials for bellows in cryogenic pipes are stainless steel, nickel alloy, and titanium. These materials have high strength and good corrosion resistance at low temperatures. It is important to select a material that can withstand the extreme temperatures and pressures of cryogenic fluids.
To ensure the flexibility and durability of the bellows at cryogenic temperatures, it is important to use materials that have been tested and approved for use in cryogenic applications. The design of the bellows should also take into consideration the thermal expansion and contraction of the material to prevent any damage or failure.
Yes, there are several special considerations for designing bellows in cryogenic pipes. These include ensuring proper insulation to prevent heat transfer, selecting appropriate materials that can withstand low temperatures, and considering the movement and flexibility needed for the specific application. It is also important to follow industry standards and guidelines for cryogenic piping design.
The most common method for testing bellows in cryogenic pipes is through hydrostatic or pneumatic pressure testing. This involves applying pressure to the bellows and monitoring for any leaks or failure. It is also recommended to conduct visual inspections and perform stress analysis to ensure the bellows will function properly under extreme conditions.