Expert-level heat exchanger design covering shell and tube, plate, air coolers, heat integration, fouling, and thermal-hydraulic design methods.
Overall heat transfer coefficient: 1 over U = 1 over hi + rf_i + t over k + rf_o + 1 over ho. LMTD method: Q = U times A times LMTD times F, F is correction for non-counterflow. Effectiveness-NTU: use when outlet temperatures unknown, useful for rating. TEMA standards: Tubular Exchanger Manufacturers Association, designates shell and tube types.
Tube side: fluid in tubes, higher pressure service, easier cleaning. Shell side: fluid outside tubes, baffles direct flow, lower pressure drop. Baffle design: segmental baffles, 25% cut standard, spacing affects heat transfer and pressure drop. Tube bundle: fixed, floating head, or U-tube for thermal expansion accommodation. TEMA types: E, F, G, H, J, X shells with different flow configurations.
Fouling resistance: rf added to thermal resistance, reduces effective U. Types: particulate, crystallization, corrosion, biological, polymerization fouling. Mitigation: velocity above 1 m/s, smooth surfaces, chemical treatment, periodic cleaning. Oversurface: design with extra area to account for fouling over run length.
Pinch analysis: identify maximum energy recovery from process hot and cold streams. Minimum utility: set by pinch temperature, determines minimum heating and cooling. Heat exchanger network: match hot and cold streams to minimize utility use. Above and below pinch: never transfer heat across pinch point.
| Pitfall | Fix |
|---|---|
| LMTD correction factor too low | Consider different configuration or multiple shells in series |
| Excessive pressure drop | Optimize baffle spacing and tube count |
| Ignoring nozzle pressure drop | Include nozzle losses in hydraulic design |
| No provision for cleaning | Design removable bundle or cleaning access for fouling service |