RELIEF SIZING

1. RELIEF SIZING ERT 312SAFETY & LOSS PREVENTION IN BIOPROCESS

2. OBJECTIVES • (A) Spring operated reliefs in liquid and gas service. • (B)Rupture disc reliefs in liquid and gas service. • (C)Vents for low pressure and high pressure. • Calculate the size of various relief apparatus used in different situation.

3. Relief sizing calculations are performed to: Determine the vent area of the relief device The procedure involved: • To determine the rate of material release • Using an appropriate equation (hydrodynamic principles), to determine the relief device vent area

4. Relief vent area calculation depends on: b) type of relief device (spring or rupture disc) a) type of flow (liquid, vapor or two-phase)

5. A relief pressure is designed to maintain the pressure at the set pressure. Normally, relief devices are specified for overpressures from 10 to 25% Figure 10-1

6. Conventional Spring operated reliefs in liquid service P drop across the relief • Liquid velocity through the spring relief: • Relief area: A = the computed relief area (in2). Qv = the volumetric flow through the relief (gpm), C0 = the discharge coefficient (unitless), (ρ / ρref) = the specific gravity of the liquid (unitless), ΔP = the pressure drop across the spring relief (lb/in2). Kv = the viscosity correction (unitless), Kp = the overpressure correction (unitless), Kb = the backpressure correction (unitless), Ps = the gauge set pressure (lb/in2), and Pb = the gauge backpressure (lb/in2).

7. For most reliefs the Renolds no. is greater than 5000, and the correction is near 1.

10. Definitions • Set pressure – the gauge pressure at which the relief begins to activate. • Maximum allowable working pressure (MAWP) – the maximum gauge pressure permissible at the top of a vessel for a designated temperature. • Operating pressure – the gauge pressure during normal service, usually 10% below the MAWP.

11. Definitions • Overpressure – the pressure increase in the vessel over the set pressure during the relieving process. • Backpressure – the pressure at the outlet of the relief device process resulting from pressure in the discharge system. • Refer to Figure 8-3.

12. Example 9-1 A positive displacement pump pumps water at 200 gpm at a pressure of 200 psig. Because a dead- headed pump can be easily damaged, compute the area required to relieve the pump, assuming a backpressure of 20 psig and a 10% overpressure. Solution a. The set pressure is 200 psig. The backpressure is specified as 20 psig and the overpressure is 10% of the set pressure, or 20 psig.

14. Spring operated reliefs in gas service • Vapor discharge mass flow

15. Relief vent area for Ideal gas Relief vent area for Non-ideal gas

16. The constant X can be calculated using Equation 9-10. Refer Example 9-2

19. Rupture disc reliefs in liquid service • Relief area: A = the computed relief area (in2). Qv = the volumetric flow through the relief (gpm), C0 = is the discharge coefficient (unitless), (ρ / ρref) is the specific gravity of the liquid (unitless), ΔP = the pressure drop across the spring relief (lb/in2).

20. Rupture disc reliefs in gas service • Flow of vapor through rupture discs: • Where discharge coefficient C0 = 1.0

21. Example 9-3 Determine the diameter of a rupture disc required to relieve the pump of Example 9-1, part a. Solution The pressure drop across the rupture disc is The specific gravity of the water (ρ/ρref) is 1.0. • A conservative discharge coefficient of 0.61 is assumed.

22. Substituting into Equation 9-3, we obtain

23. ASSIGNMENT IN CLASS – RELIEF SIZING Estimate the diameter of spring-type liquid reliefs for the following conditions: