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Process Heat Transfer

Process Heat Transfer. The Cause and Effect of Various Design Concepts. Exchanger Variables. Fouled surface area Non-condensible gases Flooded surface area Variable process inlet and outlet temperatures Variable process flow rates

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Process Heat Transfer

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  1. Process Heat Transfer The Cause and Effect of Various Design Concepts

  2. Exchanger Variables • Fouled surface area • Non-condensible gases • Flooded surface area • Variable process inlet and outlet temperatures • Variable process flow rates • All of these change the BTU demand on the heater, changing the pressure and temperature of the heat transfer media

  3. Fouled Surface Area • Fouled surface area decreases the heat transfer efficiency of the tube bundle • This inherently causes adjustments in the pressure and/or temperature of the heat transfer media being supplied to the exchanger

  4. Fouled Surface Area • Resulting in more surface exposed to the transfer media in a level control system. This will increase the BTU transfer rate. • Higher delivery pressure from the inlet control valve decreases the efficiency of the heat exchanger. Higher pressure lacks the same latent heat content of lower pressure. Energy consumption will increase, while production levels remain unchanged.

  5. Non-Condensible Gases • Presence of non-condensibles’ occupies valuable steam space • A reduction of viable heat transfer area can result due to the insulating properties • Promotion of carbonic acid formation is inherent • Excessive amounts can inhibit drainage

  6. Flooded Surface Area • Promotes corrosion and fouling • Can develop into water hammer • Controls process temperature by decreasing available surface area for heat transfer (Level Control) • Typically causes process outlet variations

  7. Variable Process Inlet & Outlet Temperatures • Changes the BTU exchange rate required or (Delta T) • These variable temperatures can increase or decrease exiting pressure based on condensing rate of the heater • Will promote flooding on low exchange rate demand

  8. Variable Process Flow Rates • Variable flows will change BTU demand on the exchanger • Higher flow rates will increase the surface area needed, raising or lowering the outlet pressure based on available surface area • Lower flow rates will decrease surface area needed, raising or lowering the outlet pressure based on available surface area

  9. Control Options • Level Control • Steam Control

  10. Level Control • Level control systems flood exchangers to reduce the amount of useable surface area for BTU transfer • Exchangers run flooded due to the control valve on the condensate outlet, modulating to maintain the desired process outlet temperature

  11. Steam Control • Allows the exchanger to run at the lowest possible steam pressure, which maximizes energy efficiency due to latent heat content • Less energy consumed for the same amount of product produced

  12. Process Design Summary • Utilize all of the surface area • Eliminate corrosion and fouling by keeping the exchanger dry • Eliminate non-condensibles • Optimize the design by using the lowest pressure steam, to gain more latent heat content per pound

  13. Operating Characteristics

  14. Filling Steam/Air In - Closed Steam/Air Out - Open Open Check Valve Step 1. During filling, the steam or air inlet and check valve on pumping trap outlet are closed. The vent and check valve on the inlet are open. Closed Check Valve

  15. Begin Pumping Steam/Air In - Open Steam/Air Out - Closed Check Valve Closed Step 2. Float Rises with level of condensate until it passes trip point, and then snap action reverses the positions shown in step one. Open Check Valve

  16. End Pumping Steam/Air - In Steam/Air - Closed Closed Check Valve Step 3. Float is lowered as level of condensate falls until snap action again reverses positions. Open Check Valve

  17. Repeat Filling Steam/Air In - Closed Steam/Air Out - Open Open Check Valve Step 4. Steam or air inlet and trap outlet are again closed while vent and condensate inlet are open. Cycle begins anew. Closed Check Valve

  18. Pump Trap Applications

  19. Process Heat Exchangerwith 100% Turndown Capability

  20. Vacuum Reboiler Construction Comparison

  21. Hydrocarbon Knockout Drum/Separator

  22. Flare Header Drain

  23. Flash Vessels

  24. Steam Turbine Casing

  25. Pump Trap Applications • Process Heat Exchangers • Liquid Separators • Sumps • Vacuum Systems • Condensate Drum – Flash Tanks • Vented Systems • Closed Loop Applications

  26. Understanding and Benefiting from Equipment Stall

  27. Q = U · A ·D T Q = Design Load (BTU/Hr) U = Manufacturer’s Heat Transfer Value (BTU/ft2/°F/Hr) A = Heat Transfer Surface Area (ft2) DT = (Ts – T2) Approaching Temperature (°F) Ts = Operating Steam Temperature (°F) T2 = Product Outlet Temperature (°F)

  28. What is wrong with this application?

  29. Effects of “Stall” • Inadequate condensate drainage • Water hammer • Frozen coils • Corrosion due to Carbonic Acid formation • Poor temperature control • Control valve hunting (system cycling) • Reduction of heat transfer capacity

  30. Factors Contributing to “Stall” • Oversized equipment • Conservative fouling factors • Excessive safety factors • Large operating ranges • Back pressure at steam trap discharge • Changes in system parameters

  31. Finding “Stall” Where does Stall occur?? • Air heating coils • Shell & tube heat exchangers • Plate & frame heat exchangers • Absorption chillers • Kettles • Any type of heat transfer equipment that has Modulating Control

  32. What is the “Stall” Solution? • Use a bigger steam trap? • Use a vacuum breaker? • Implement a safety drain? • Install a Posi-Pressure system? • Use an electric pump?

  33. Keys to Operation • How quick it can fill: This is dictated by head pressure & inlet pipe and check valve size • Vent/Equalization: Vent connection must always be in vapor space • Pump Out: Motive vs. back pressure and gas used

  34. Vocabulary Filling Head: Distance between the top of the pump and the bottom of the receiver or reservoir pipe

  35. Vocabulary (Continued) Receiver/Reservoir Pipe: This is a temporary holding place to store condensate while the pump is in the pump down cycle. The receiver/reservoir pipe is designed and sized to prevent condensate from backing up into the system.

  36. Open System Configuration Closed System Configuration

  37. Open System

  38. Open System Advantages: • Drain multiple pieces of equipment • Can use Air or Steam for pump trap operation • Easiest to understand Disadvantages: • Lose valuable flash steam • Must run a potentially expensive atmospheric vent line • Size the pump trap based total design load • Must compete with electric pumps

  39. Closed System

  40. Closed System Advantages: • No flash steam loss • No need to run long expensive vent lines • Use a smaller pump than in a open system* • Return condensate hotter Disadvantages: • Dedicated pump for a single piece of equipment • More complex • Cannot use air as motive force

  41. Pump Sizing / Receiver Sizing Pump Sizing • Determine head available from equipment (distance from equipment outlet to grade) • Select either closed loop or vented design(Note: If multiple sources of condensate, vented system must be used to prevent short circuiting)

  42. Pump Sizing / Receiver Sizing Pump Sizing • Determine maximum pumping load • Calculate maximum back pressure (including lift) • Determine motive pressure and gas to be used (use capacity correction factor if using a medium other than steam)

  43. Pump Sizing / Receiver Sizing Pump Sizing • Check and specify head pressure (distance from bottom of receiver/reservoir to top of selected pump) • Make sure to use capacity correction if more or less head is available than standard catalog dimension

  44. Pump Sizing / Receiver Sizing Pump Sizing • Calculate maximum flash rate & needed vent size – if vented system • Determine and size reservoir – if closed loop system • Size downstream F&T trap if needed for closed loop system

  45. Vented Receiver Sizing Note: When draining from a single or multiple pieces of equipment in an “open” system, a vented receiver should be installed horizontally above and ahead of the pump trap. In addition to sufficient holding volume of the condensate above the fill head of the pump trap to hold the condensate during the pump trap cycle, the receiver must also be sized to allow enough area for flash steam and condensate separation.

  46. Closed Loop Receiver Sizing Note: When draining from a single piece of equipment in a closed loop system, to achieve maximum energy efficiency a reservoir should be installed horizontally above and ahead of the pump trap. Sufficient reservoir volume is required above the filling head level to hold condensate during the pump trap discharge cycle. The chart above shows the minimum reservoir sizing, based on the condensate load, to prevent equipment flooding during the pump trap discharge cycle.

  47. Critical Design Criteria Summary • Maximum condensate flow from exchangers and reboilers • Maximum differential pressure across the system • Minimum differential pressure across the system (specifically when clean) • Minimum tower height needed to achieve maximum condensate flow rate at minimum differential • Maximum motive pressure (steam, air, nitrogen, etc.) available to power pumps

  48. Critical Design Criteria Summary • Maximum instantaneous discharge rate for downstream pipe sizing & trap sizing • Temperature differential of condensate source vs. condensate header design • Piping layout to prevent hydraulic shock • Total installed cost savings, including construction, on turnkey jobs • Integrity of mechanical design due to the critical nature of the service • Minimize potential problems with proper designs

  49. Maximum Differential Pressure Across the System • Maximum pressure from control valve, including minimal drop • Minimum drop across exchanger • Maximum pressure – should tube leak occur • Elimination of back pressure (bypass to grade) • Consider fouled surface area

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