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Procedure for Vibration Predictions

DOI 10.1615/hedhme.a.000444

4.6.5 Procedure for vibration prediction

Every design of a shell-and-tube heat exchanger should be reviewed to ensure that it is free from potential flow-induced vibration problems. Some items may require major changes in the design while others will be minor.

A. Vibration analysis primary check

A four-step primary check is suggested to minimize the probability of flow-induced vibration problems. The steps can be taken in any order and should be repeated for the inlet, central, and outlet regions. For a high probability of not having vibration, it must not be predicted for any of the following steps:

Step 1. Acoustic vibration. For a gas or vapor as the shell-side fluid, compare the vortex shedding frequency fvs (Equation 443.2 with u = uc and Figure 443.2) and turbulent buffeting frequency ftb (Equation 443.3) with the acoustic frequency fa (Equation 443.6). If cither is within 20% of fa acoustic vibration is possible.

Step 2. Fluid clastic instability. For either gas or liquid as the shell-side fluid, compare the cross-flow velocity uc with the critical velocity ucrit to initiate fluid clastic instability (Equation 443.4. Figure 443.4, and δ0 = 0.03 for gases and vapors and = 0.10 for liquids and two-phase mixtures). Vibration and damage are probable when uc is greater than ucrit.

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