API RP 520-2:2003 pdf download

API RP 520-2:2003 pdf download.Sizing, Selection, and Installation of Pressure-Relieving Devices in Refineries Part ll–Installation.
4.6 RUPTURE DISK DEVICES IN COMBINATION WITH PRESSURE-RELIEF VALVES
A rupture disk device may be used as the sole pressure- relief device, or it may be installed between a pressure-relief valve and the vessel or on the downstream side of a pressure- relief valve (see Figure 8).
When a rupture disk device is used between the pressure- relief valve and the protected vessel, the space between the nipture disk and the pressure-relief valve shall have a free vent, pressure gauge, trycock, or other suitable telltale indicator. A non-vented space with a pressure gage without alarms or other indication devices is not recommended as a suitable telltale indicator. Users are warned that a rupture disk will not burst in tolerance if back pressure builds up in a non-vented space between the rupture disk and the pressure-relief valve, which will occur should leakage develop in the rupture disk due to corrosion or other cause. Only non-fragmenting rupture disk devices may be used beneath a pressure-relief valve.
Rupture disks may not be available in all sizes at lower pressures; therefore, for these low-pressure applications the available rupture disk may have to be larger than the nominal size of the inlet piping and pressure-relief valve.
Refer to API RP 520. Part I for additional information related to the combination capacity factor when a rupture disk is installed in combination with a pressure-relief valve.
4.7 PROCESS LATERALS CONNECTED TO INLET PIPING OF PRESSURE-RELIEF VALVES
Process laterals should generally not be connected to the inlet piping of pressure-relief valves (see Figure 9). Exceptions should be analyzed carefully to ensure that the allowable pressure drop at the inlet of the pressure-relief valve is not exceeded under simultaneous conditions of rated flow through the pressure-relief valve and maximum possible flow through the process lateral.
4.8 11JRBULENCE IN PRESSURE-RELIEF DEVICE INLETS
See 9.3 for information regarding the effects of turbulence on pressure-relief valves.
5 Discharge Piping From Pressure-Relief Devices
5.1 GENERAL REQUIREMENTS
For general requirements for discharge piping, see Figures 1, 2. 7, and 10.
The discharge piping installation must provide for proper pressure-relief device performance and adequate drainage (free-draining systems are preferred—see Section 8). Consideration should be given to the type of discharge system used, the back pressure on the pressure-relief device, and the set-pressure relationship of the pressure-relief devices in the system.
Auto-refrigeration during discharge can cool the outlet of the pressure-relief device and the discharge piping to the point that brittle fracture can occur. Piping design, including material selection, must consider the expected discharge temperature.
5.2 SAFE DISPOSAL OF RELIEVING FLUIDS
For a comprehensive source of information about the safe disposal of various relieving fluids, see API RP 521.
5.3 BACK PRESSURE LIMITATIONS AND SIZING
OF PIPE
When discharge piping for pressure-relief valves is designed, consideration should he given to the combined effect of superimposed and built-up back pressure on the operating characteristics of the pressure-relief devices. The discharge pipmg system should he designed so that the back pressure does not exceed an acceptable value for any pressure-relief device in the system. See API RP 520 Part I for limitations on hack pressure.
When rupture disks are used as the sole relieving device and the discharge is to a closed system, the effect of the superimposed back pressure on the bursting pressure for the disk must be considered.
The rated capacity of a conventional spring loaded, balanced spring loaded or pop action pilot-operated pressure- relief valve should typically be used to size the atmospheric vent piping or the discharge line from the pressure-relief valve to the relief header. Common relief header piping in closed discharge systems should be sized using the protected system’s required relieving capacity.
For a modulating pilot-operated pressure-relief valve, the discharge piping can be sized using the required relieving capacity of the system that the valve is protecting.
Whenever the atmospheric vent. discharge piping or common relief header piping is sized using the system’s required relieving capacity instead of the rated capacity of the valve, the back pressure should be re-checked whenever changes are made to the process that effect the required relieving capacity.