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Define concept of relief Describe and Discuss the relief
locations, types, scenarios. Discuss the relief system in specific
unit operations.
1. Inherent safety – plant design consideration
2. Better process control – control systems, alarms, safety shutdown systems
3. Install relief systems – to relieve liquids or gases before excessive pressure are developed.
Relief systems compose of the relief device and the
associated downstream process equipment & safety handle the material ejected.
Pressure relief systems are required for the following reasons:
• to protect personnel from the dangers of overpressurizing equipment,
• to minimize chemical losses during pressure upsets,
• to prevent damage to equipment,• to prevent damage to adjoining property,• to reduce insurance premiums,• to comply with governmental regulations.
Assume that an exothermic reaction is occurring within a reactor.
If cooling is lost because of a loss of cooling water supply, failure of a valve, or other scenario, then the reactor temperature will rise.
As the temperature rises, the reaction rate
increases leading to an increase in heat production. This self-accelerating mechanism results in
a runaway reaction.
The pressure within the reactor increases because of increased vapor pressure of the liquid components and/or gaseous decomposition products resulting from the high temperature.
Reaction runaways for large commercial reactors can occur in minutes, with temperature and pressure increases of several hundred degrees per minute and several hundred psi per minute, respectively.
What happen if the reactor has no relief system?
Figure 8-2 Pressure versus time for runaway reactions: (A) relieving vapor, (B) relieving froth (two-phase flow), and (C) closed reaction vessel.
Curve C – reactor has no relief system- P and T increases until the reactant
are completely consumed.- after the reactants are consumed, the
heat generation stop and the pressure subsequently drop.
Curve B - has a relief system (two phase froth)- The pressure increase until the relief
device activates Curve A – has a relief system (vapor relief only)
- The pressure drop immediately when the relief device opens
The network of components around a relief device, including the pipe to the relief, the relief device, discharge pipelines, knockout drum, scrubber, flare, or other types of equipment that assist in the safe relief process.
Pressure relief devices are installed at every point identified as potentially hazardous (potential problems that may result in increased pressures)
Guidelines for specifying relief positions:1. All vessels – reactors, storage tanks, towers
and drums.2. Positive displacement pumps, compressors
and turbines need reliefs on the discharged side.
3. Blocked-in section of cool liquid-filled lines that exposed to heat such as heat exchanger
& cooling coil4. Vessel steam jackets
Specify the location of reliefs in the simple polymerization reactor system illustrated in Figure 8-5. The major steps in this polymerization process include:
(1) pumping 100 lb of initiator into reactor R-1, (2) heating to the reaction temperature of 240°F, (3) adding monomer for a period of 3 hr, and(4) stripping the residual monomer by means of a vacuum using valve V-15.
Because the reaction is exothermic, cooling during monomer addition with cooling water is necessary.
Figure 8-5 Polymerization reactor without Safety reliefs.
Figure 8-6 Polymerization reactor with safety reliefs.
Refer to Figures 8-5 and 8-6 and Table 8-1 for relief locations.
a. Reactor (R-1): A relief is installed on this reactor because, in general, every process vessel needs a relief. This relief is labeled PSV-1 for pressure safety valve 1.
b. Positive displacement pump (P-1): Positive displacement pumps are overloaded,
overheated, and damaged if they are dead-headed without a pressure-relieving device (PSV-2). This type of relief discharge is usually
recycled back to the feed vessel.
c. Heat exchanger (E-1): Heat exchanger tubes can rupture from excessive pressures when water is blocked in (V-10 and V-11 are closed) and the exchanger is heated (by steam, for example). This hazard is eliminated by adding PSV-3.
d. Drum (D-1): Again, all process vessels need relief valves, PSV-4.
e. Reactor coil: This reactor coil can be pressure- ruptured when water is blocked in (V-4, V-5,V-6, and V-7 are closed) and the coil is heated with steam or even the sun. Add PSV-5 to this coil.
Specific types of relief devices are chosen for specific applications:
- for liquid, - gases,- liquid & gases, - solid - corrosive materials
2 categories of relief devices:a) spring-operated valves
1. conventional2. balanced-bellows
- relief set pressure – 10% above the normal operating pressure.
b) rupture discs- Rupture discs are specially designed to rupture at a
specified relief set pressure. - can be made from exotic corrosion-resistant
material- problem: once it open, it remain open – lead to
complete discharge of process material.
Rupture discs are frequently installed in series to a spring-loaded relief (1) to protect an expensive spring-loaded device from a corrosive environment, (2) to give absolute isolation when handling extremely toxic chemicals (spring-loaded reliefs may weep), (3) to give absolute isolation when handling flammable gases, (4) to protect the relatively complex parts of a spring- loaded device from reactive monomers that could cause plugging, (5) to relieve slurries that may plug spring-loaded devices.
3 sub-category types of spring-loaded pressure reliefs:
1. The relief valve is primarily for liquid service. - The relief valve (liquid only) begins to open at the set pressure. - This valve reaches full capacity when the pressure reaches 25% overpressure. - The valve closes as the pressure returns
to the set pressure.
2. The safety valve is for gas service. - Safety valves pop open when the pressure exceeds the set pressure.
3. The safety relief valve is used for liquid and gas service.
- Safety relief valves function as relief valves for liquids and as safety valves for gases.
Example 8.2
Specify the types of relief devices needed for the polymerization reactor in Example 8-1 (see Figure 8-6).
Figure 8-6 Polymerization reactor with safety reliefs.
Solution
Each relief is reviewed in relation to the relief system and the properties of the relieved fluids:
a. PSV-la is a rupture disc to protect PSV-lb from the reactive monomers (plugging from polymerization).
b. PSV-lb is a safety relief valve because a runaway reaction will give two-phase flow, both liquid and vapor.
c. PSV-2 is a relief valve because this relief is in a liquid service line. A conventional valve is satisfactory.
d. PSV-3 is a relief valve because it is for liquid only. A conventional relief device is satisfactory in this service.
e. PSV-4 is a safety relief valve because liquid or vapor service is possible. Because this vent will go to a scrubber with possibly large backpressures, a balanced bellows is specified.
f. PSV-5 is a relief valve for liquid service only. This relief provides protection for the following scenario: The liquid is blocked in by closing all valves; the heat of reaction increases the temperature of the surrounding reactor fluid; and pressures are increased inside the coil be cause of thermal expansion.
A relief scenario is a description of one specific relief event.
Usually each relief has more than one relief event, and the worst-case scenario is the scenario or event that requires the largest relief vent area.
Figure 8-6 Polymerization reactor with safety reliefs.
A relief system rarely vented to the atmosphere. A relief is discharged to a knockout system to
separate the liquid from the vapor. The liquid is collected The vapor is discharged to another treatment unit
depends on the hazards of the vapor The vapor treatment unit: condenser, scrubber,
incinerator, flare or combination of them. This system is called a total containment system
(Fig 8-12).
Figure 8-12 Relief containment system with blowdown drum. The blowdown drum separates the vapor from the liquid.
Catch tanks or blowdown drums Serves as vapor-liquid separator Two phase mixture usually enters at one end,
and the vapor leaves at the opposite end The design method for sizing this system is
based on the maximum allowable velocity for minimizing liquid entrainment.
The dropout velocity of particle in a stream is:
Where;ud = dropout velocityg = acceleration due to gravitydp = particle diameterρL = liquid densityρv = vapor densityC = drag coefficient
C
gdu
V
VLpd
15.1
Where;μv = vapor viscosity in centipoiseC(Re)2 = unitless
2
3
3
2
3
282 1095.0(Re)
v
VLpVd
ftftlb
centipoiseC
Figure 8-14 Drag coefficient correlation
Example 8-3
Determine the maximum vapor velocity in a horizontal knockout drum to dropout liquid particles with particle diameters of 300μm, where;
Sometimes used after knockout drums Objective: to burn the combustible or toxic gas to
produce combustion products The diameter of the flare must be suitable to
maintain a stable flame and to prevent blowout The height of flare is fixed on the basis of the
heat generated and the resulting potential damage to equipment and humans.
Height of flare, Hf:
Where;df = flare stack diameter (ft)qf = heat intensity (Btu/hr/ft2)Xf = distance from the base of the flare (ft)M = molecular weightQm = vapor rate
Example 8.4Determine the stack height required to give a heat
intensity of 1500 Btu/hr/ft2 at a distance of 410 ft from the base of the flare. The flare diameter is 4 ft, the flare load is 970,000 lb/hr, and the molecular weight of the vapor is 44.
Solution
If the vapor is toxic, a scrubber system may be required.
Scrubber system can be:- packed columns- plate columns- venturi-type systems
Alternative to treat exiting vapors For vapor with high boiling point and if the
recovered condensate is valuable.