Pressure Relief valve used in flow line to release the over pressure at our desired pressure
cannyengineerings
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52 slides
Jun 12, 2024
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About This Presentation
Pressure Relief valve used in flow line to release the over pressure at our desired pressure
Slide Content
1/51
Pressure Relief
“Grace under pressure”
–Ernest Hemingway
Harry J. Toups LSU Department of Chemical Engineering with
significant material from SACHE 2003 Workshop presentation
by Scott Ostrowski (ExxonMobil)
and Professor EmeritusArt Sterling
Pressure Relief
“Grace under pressure”
–Ernest Hemingway
Harry J. Toups LSU Department of Chemical Engineering with
significant material from SACHE 2003 Workshop presentation
by Scott Ostrowski (ExxonMobil)
and Professor EmeritusArt Sterling
2/51
What is the Hazard?
Despite safety precautions …
–Equipment failures
–Human error, and
–External events, can sometimes lead to …
Increases in process pressuresbeyond safe
levels, potentially resulting in …
OVERPRESSURE due to a RELIEF EVENT
What is the Hazard?
Despite safety precautions …
–Equipment failures
–Human error, and
–External events, can sometimes lead to …
Increases in process pressuresbeyond safe
levels, potentially resulting in …
OVERPRESSURE due to a RELIEF EVENT
3/51
What are Relief Events?
External fire
Flow from high pressure source
Heat input from associated equipment
Pumps and compressors
Ambient heat transfer
Liquid expansion in pipes and surge
What are Relief Events?
External fire
Flow from high pressure source
Heat input from associated equipment
Pumps and compressors
Ambient heat transfer
Liquid expansion in pipes and surge
4/51
Potential Lines of Defense
Inherently Safe Design
Passive Control
Active Control
–Low pressure processes
–Install Relief Systems
–Overdesign of process equipment
Potential Lines of Defense
Inherently Safe Design
Passive Control
Active Control
–Low pressure processes
–Install Relief Systems
–Overdesign of process equipment
5/51
What is a Relief System?
A relief device, and
Associated lines and process
equipment to safely handle the material
ejected
What is a Relief System?
A relief device, and
Associated lines and process
equipment to safely handle the material
ejected
6/51
Why Use a Relief System?
Inherently Safe Designsimply can’t
eliminate every pressure hazard
Passive designscan be exceedingly
expensive and cumbersome
Relief systemswork!
Why Use a Relief System?
Inherently Safe Designsimply can’t
eliminate every pressure hazard
Passive designscan be exceedingly
expensive and cumbersome
Relief systemswork!
7/51
Pressure Terminology
MAWP
Design pressure
Operating
pressure
Set pressure
Overpressure
Accumulation
Blowdown
Pressure Terminology
MAWP
Design pressure
Operating
pressure
Set pressure
Overpressure
Accumulation
Blowdown
8/51
Code Requirements
General Code requirements include:
–ASME Boiler & Pressure Vessel Codes
–ASME B31.3 / Petroleum Refinery Piping
–ASME B16.5 / Flanges & Flanged Fittings
Code Requirements
General Code requirements include:
–ASME Boiler & Pressure Vessel Codes
–ASME B31.3 / Petroleum Refinery Piping
–ASME B16.5 / Flanges & Flanged Fittings
9/51
Code Requirements
Relieving pressure shall not exceed
MAWP (accumulation) by more than:
–3% for fired and unfired steam boilers
–10% for vessels equipped with a single
pressure relief device
–16% for vessels equipped with multiple
pressure relief devices
–21% for fire contingency
Code Requirements
Relieving pressure shall not exceed
MAWP (accumulation) by more than:
–3% for fired and unfired steam boilers
–10% for vessels equipped with a single
pressure relief device
–16% for vessels equipped with multiple
pressure relief devices
–21% for fire contingency
10/51
Relief Design Methodology
LOCATE
RELIEFS
CHOOSE
TYPE
DEVELOP
SCENARIOS
SIZE RELIEFS
(1 or 2 Phase)
CHOOSE
WORST CASE
DESIGN RELIEF
SYSTEM
Relief Design Methodology
LOCATE
RELIEFS
CHOOSE
TYPE
DEVELOP
SCENARIOS
SIZE RELIEFS
(1 or 2 Phase)
CHOOSE
WORST CASE
DESIGN RELIEF
SYSTEM
11/51
Locating Reliefs –Where?
All vessels
Blocked in sections of cool liquid lines
that are exposed to heat
Discharge sides of positive
displacement pumps, compressors,
and turbines
Vessel steam jackets
Where PHA indicates the need
LOCATE
RELIEFS
Locating Reliefs –Where?
All vessels
Blocked in sections of cool liquid lines
that are exposed to heat
Discharge sides of positive
displacement pumps, compressors,
and turbines
Vessel steam jackets
Where PHA indicates the need
LOCATE
RELIEFS
12/51
Choosing Relief Types
Spring-Operated Valves
Rupture Devices
CHOOSE
TYPE
Choosing Relief Types
Spring-Operated Valves
Rupture Devices
CHOOSE
TYPE
13/51
Spring-Operated Valves
Conventional Type
CHOOSE
TYPE
Spring-Operated Valves
Conventional Type
CHOOSE
TYPE
14/51
Picture: Conventional Relief
Valve
Conventional
Relief Valve
CHOOSE
TYPE
Picture: Conventional Relief
Valve
Conventional
Relief Valve
CHOOSE
TYPE
15/51
Superimposed Back
Pressure
Pressure in
discharge header
before valve opens
Can be constant or
variable
CHOOSE
TYPE
Superimposed Back
Pressure
Pressure in
discharge header
before valve opens
Can be constant or
variable
CHOOSE
TYPE
16/51
Built-up Back Pressure
Pressure in
discharge header
due to frictional
losses after valve
opens
Total =
Superimposed +
Built-up
CHOOSE
TYPE
Built-up Back Pressure
Pressure in
discharge header
due to frictional
losses after valve
opens
Total =
Superimposed +
Built-up
CHOOSE
TYPE
17/51
Spring-Operated Valves
Balanced Bellows Type
CHOOSE
TYPE
Spring-Operated Valves
Balanced Bellows Type
CHOOSE
TYPE
18/51
Picture: Bellows Relief
ValveBellows
Relief Valve
CHOOSE
TYPE
Picture: Bellows Relief
ValveBellows
Relief Valve
CHOOSE
TYPE
19/51
Pros & Cons:
Conventional Valve
Advantages
+Most reliable type if properly sized and operated
+Versatile --can be used in many services
Disadvantages
–Relieving pressure affected by back pressure
–Susceptible to chatter if built-up back pressure is
too high
CHOOSE
TYPE
Pros & Cons:
Conventional Valve
Advantages
+Most reliable type if properly sized and operated
+Versatile --can be used in many services
Disadvantages
–Relieving pressure affected by back pressure
–Susceptible to chatter if built-up back pressure is
too high
CHOOSE
TYPE
20/51
Pros & Cons:
Balanced Bellows Valve
Advantages
+Relieving pressure not affected by back pressure
+Can handle higher built-up back pressure
+Protects spring from corrosion
Disadvantages
–Bellows susceptible to fatigue/rupture
–May release flammables/toxics to atmosphere
–Requires separate venting system
CHOOSE
TYPE
Pros & Cons:
Balanced Bellows Valve
Advantages
+Relieving pressure not affected by back pressure
+Can handle higher built-up back pressure
+Protects spring from corrosion
Disadvantages
–Bellows susceptible to fatigue/rupture
–May release flammables/toxics to atmosphere
–Requires separate venting system
CHOOSE
TYPE
21/51
Rupture Devices
Rupture Disc
Rupture Pin
CHOOSE
TYPE
Rupture Devices
Rupture Disc
Rupture Pin
CHOOSE
TYPE
22/51
Conventional
Metal Rupture Disc
CHOOSE
TYPE
Conventional
Metal Rupture Disc
CHOOSE
TYPE
23/51
Conventional
Rupture Pin Device
CHOOSE
TYPE
Conventional
Rupture Pin Device
CHOOSE
TYPE
24/51
When to Use a Spring-
Operated Valve
Losing entire contents is unacceptable
–Fluids above normal boiling point
–Toxic fluids
Need to avoid failing low
Return to normal operations quickly
Withstand process pressure changes,
including vacuum
CHOOSE
TYPE
When to Use a Spring-
Operated Valve
Losing entire contents is unacceptable
–Fluids above normal boiling point
–Toxic fluids
Need to avoid failing low
Return to normal operations quickly
Withstand process pressure changes,
including vacuum
CHOOSE
TYPE
25/51
When to Use a Rupture
Disc/Pin
Capital and maintenance savings
Losing the contents is not an issue
Benign service (nontoxic, non-
hazardous)
Need for fast-acting device
Potential for relief valve plugging
High viscosity liquids
CHOOSE
TYPE
When to Use a Rupture
Disc/Pin
Capital and maintenance savings
Losing the contents is not an issue
Benign service (nontoxic, non-
hazardous)
Need for fast-acting device
Potential for relief valve plugging
High viscosity liquids
CHOOSE
TYPE
26/51
When to Use Both Types
Need a positive seal (toxic material,
material balance requirements)
Protect safety valve from corrosion
System contains solids
CHOOSE
TYPE
When to Use Both Types
Need a positive seal (toxic material,
material balance requirements)
Protect safety valve from corrosion
System contains solids
CHOOSE
TYPE
27/51
Relief Event Scenarios
A description of one specific relief event
Usually each relief has more than one relief
event, more than one scenario
Examples include:
–Overfilling/overpressuring
–Fire
–Runaway reaction
–Blocked lines with subsequent expansion
Developed through Process Hazard Analysis
(PHA)
DEVELOP
SCENARIOS
Relief Event Scenarios
A description of one specific relief event
Usually each relief has more than one relief
event, more than one scenario
Examples include:
–Overfilling/overpressuring
–Fire
–Runaway reaction
–Blocked lines with subsequent expansion
Developed through Process Hazard Analysis
(PHA)
DEVELOP
SCENARIOS
28/51
An Example: Batch Reactor
Control valve on
nitric acid feed line
stuck open, vessel
overfills
Steam regulator to
jacket fails, vessel
overpressures
Coolant system
fails, runaway
reaction
DEVELOP
SCENARIOSProduct
Raw
Material
Feeds
Organic substrate
Catalyst
Nitric Acid
Reactor ~ 100 gallons
An Example: Batch Reactor
Control valve on
nitric acid feed line
stuck open, vessel
overfills
Steam regulator to
jacket fails, vessel
overpressures
Coolant system
fails, runaway
reaction
DEVELOP
SCENARIOSProduct
Raw
Material
Feeds
Organic substrate
Catalyst
Nitric Acid
Reactor ~ 100 gallons
29/51
Sizing Reliefs
Determining relief rates
Determine relief vent area
SIZE RELIEFS
(Single Phase)
Sizing Reliefs
Determining relief rates
Determine relief vent area
SIZE RELIEFS
(Single Phase)
30/51
Scenarios Drive Relief Rates
Overfill (e.g., control valve failure)
Fire
Blocked discharge
SIZE RELIEFS
(Single Phase)
–Maximum flow rate thru valve into vessel
–Vaporization rate due to heat-up
–Design pump flow rate
Scenarios Drive Relief Rates
Overfill (e.g., control valve failure)
Fire
Blocked discharge
SIZE RELIEFS
(Single Phase)
–Maximum flow rate thru valve into vessel
–Vaporization rate due to heat-up
–Design pump flow rate
31/51
Overfill Scenario Calcs
Determined maximum flow thru valve
(i.e., blowthrough)
Liquids:
Gases:
SIZE RELIEFS
(Single Phase)PgACQ
cvm
2 )1/()1(
1
2
og
c
ovchokedm
TR
Mg
APCQ
Overfill Scenario Calcs
Determined maximum flow thru valve
(i.e., blowthrough)
Liquids:
Gases:
SIZE RELIEFS
(Single Phase)PgACQ
cvm
2 )1/()1(
1
2
og
c
ovchokedm
TR
Mg
APCQ
32/51
Fire Scenario Calcs
API 520 gives all equations for
calculating fire relief rate, step-by-step
1.Determine the total wetted surface area
2.Determine the total heat absorption
3.Determine the rate of vapor or gas
vaporized from the liquid
SIZE RELIEFS
(Single Phase)
Fire Scenario Calcs
API 520 gives all equations for
calculating fire relief rate, step-by-step
1.Determine the total wetted surface area
2.Determine the total heat absorption
3.Determine the rate of vapor or gas
vaporized from the liquid
SIZE RELIEFS
(Single Phase)
33/51
Determine Wetted Area
SIZE RELIEFS
(Single Phase)
180/
wet
BDLEDA
DEB 21cos
1
Determine Wetted Area
SIZE RELIEFS
(Single Phase)
180/
wet
BDLEDA
DEB 21cos
1
34/51
Determine Heat Absorption
Prompt fire-fighting & adequate
drainage:
Otherwise:
where
SIZE RELIEFS
(Single Phase)82.0
wet
000,21
Btu/hr
AFQ 82.0
wet
500,34
Btu/hr
AFQ
Q is the heat absorption (Btu/hr)
F is the environmental factor
–1.0 for a bare vessel
–Smaller values for insulated vessels
A
wetis the wetted surface area (ft
2
)
Determine Heat Absorption
Prompt fire-fighting & adequate
drainage:
Otherwise:
where
SIZE RELIEFS
(Single Phase)82.0
wet
000,21
Btu/hr
AFQ 82.0
wet
500,34
Btu/hr
AFQ
Q is the heat absorption (Btu/hr)
F is the environmental factor
–1.0 for a bare vessel
–Smaller values for insulated vessels
A
wetis the wetted surface area (ft
2
)
35/51
Determine Vaporization
Ratevap
/HQW
where
W = Mass flow, lbs/hr
Q = Total heat absorption to
the wetted surface, Btu/hr
H
vap= Latent heat of
vaporization, Btu/lb
SIZE RELIEFS
(Single Phase)
Determine Vaporization
Ratevap
/HQW
where
W = Mass flow, lbs/hr
Q = Total heat absorption to
the wetted surface, Btu/hr
H
vap= Latent heat of
vaporization, Btu/lb
SIZE RELIEFS
(Single Phase)
36/51
Determine Relief Vent Area
Liquid
Service
wherebs
25.1
)
ref
(
bpvo
v
Q
gpm 38.0
2/1)psi(2in
PPKKKC
A
A is the computed relief area (in
2
)
Q
vis the volumetric flow thru the relief (gpm)
C
ois the discharge coefficient
K
vis the viscosity correction
K
pis the overpressure correction
K
bis the backpressure correction
(/
ref) is the specific gravity of liquid
P
sis the gauge set pressure (lb
f/in
2
)
P
bis the gauge backpressure (lb
f/in
2
)
SIZE RELIEFS
(Single Phase)
Determine Relief Vent Area
Liquid
Service
wherebs
25.1
)
ref
(
bpvo
v
Q
gpm 38.0
2/1)psi(2in
PPKKKC
A
A is the computed relief area (in
2
)
Q
vis the volumetric flow thru the relief (gpm)
C
ois the discharge coefficient
K
vis the viscosity correction
K
pis the overpressure correction
K
bis the backpressure correction
(/
ref) is the specific gravity of liquid
P
sis the gauge set pressure (lb
f/in
2
)
P
bis the gauge backpressure (lb
f/in
2
)
SIZE RELIEFS
(Single Phase)
37/51
Determine Relief Vent Area
Gas
Service
whereM
Tz
PKC
A
bo
m
Q
A is the computed relief area (in
2
)
Q
mis the discharge flow thru the relief (lb
m/hr)
C
ois the discharge coefficient
K
bis the backpressure correction
T is the absolute temperature of the discharge (°R)
z is the compressibility factor
M is average molecular weight of gas (lb
m/lb-mol)
P is maximum absolute discharge pressure (lb
f/in
2
)
is an isentropic expansion function
SIZE RELIEFS
(Single Phase) valverelief for the pressureset theis
s
pipingfor
s
33.1
max
fire toexposed sfor vessel
s
2.1
max
vesselspressure unfiredfor
s
1.1
max
7.14
max
P
PP
PP
PP
PP
Determine Relief Vent Area
Gas
Service
whereM
Tz
PKC
A
bo
m
Q
A is the computed relief area (in
2
)
Q
mis the discharge flow thru the relief (lb
m/hr)
C
ois the discharge coefficient
K
bis the backpressure correction
T is the absolute temperature of the discharge (°R)
z is the compressibility factor
M is average molecular weight of gas (lb
m/lb-mol)
P is maximum absolute discharge pressure (lb
f/in
2
)
is an isentropic expansion function
SIZE RELIEFS
(Single Phase) valverelief for the pressureset theis
s
pipingfor
s
33.1
max
fire toexposed sfor vessel
s
2.1
max
vesselspressure unfiredfor
s
1.1
max
7.14
max
P
PP
PP
PP
PP
38/51
Determine Relief Vent Area
Gas
Service
where)1/()1(
1
25.519
is an isentropic expansion
function
is heat capacity ratio for the gas
Units are as described in previous
slide
SIZE RELIEFS
(Single Phase)
Determine Relief Vent Area
Gas
Service
where)1/()1(
1
25.519
is an isentropic expansion
function
is heat capacity ratio for the gas
Units are as described in previous
slide
SIZE RELIEFS
(Single Phase)
39/51
A Special Issue: Chatter
Spring relief devices require 25-30%
of maximum flow capacity to maintain
the valve seat in the open position
Lower flows result in chattering,
caused by rapid opening and closing
of the valve disc
This can lead to destruction of the
device and a dangerous situation
SIZE RELIEFS
(Single Phase)
A Special Issue: Chatter
Spring relief devices require 25-30%
of maximum flow capacity to maintain
the valve seat in the open position
Lower flows result in chattering,
caused by rapid opening and closing
of the valve disc
This can lead to destruction of the
device and a dangerous situation
SIZE RELIEFS
(Single Phase)
40/51
Chatter -Principal Causes
Valve Issues
–Oversized valve
–Valve handling widely differing rates
Relief System Issues
–Excessive inlet pressure drop
–Excessive built-up back pressure
SIZE RELIEFS
(Single Phase)
Chatter -Principal Causes
Valve Issues
–Oversized valve
–Valve handling widely differing rates
Relief System Issues
–Excessive inlet pressure drop
–Excessive built-up back pressure
SIZE RELIEFS
(Single Phase)
41/51
Worst Case Event Scenario
Worst case for each relief is the event
requiring the largest relief vent area
Worst cases are a subset of the overall
set of scenarios for each relief
The identification of the worst-case
scenario frequently affects relief size
more than the accuracy of sizing calcs
CHOOSE
WORST CASE
Worst Case Event Scenario
Worst case for each relief is the event
requiring the largest relief vent area
Worst cases are a subset of the overall
set of scenarios for each relief
The identification of the worst-case
scenario frequently affects relief size
more than the accuracy of sizing calcs
CHOOSE
WORST CASE
42/51
Design Relief System
Relief System is more than a safety
relief valve or rupture disc, it includes:
DESIGN RELIEF
SYSTEM
–Backup relief device(s)
–Line leading to relief device(s)
–Environmental conditioning of relief device
–Discharge piping/headers
–Blowdown drum
–Condenser, flare stack, or scrubber
Design Relief System
Relief System is more than a safety
relief valve or rupture disc, it includes:
DESIGN RELIEF
SYSTEM
–Backup relief device(s)
–Line leading to relief device(s)
–Environmental conditioning of relief device
–Discharge piping/headers
–Blowdown drum
–Condenser, flare stack, or scrubber
43/51
Installation, Inspection, and
Maintenance
To undermine all the good efforts of a
design crew, simply …
1.Improperly install relief devices
2.Fail to regularly inspect relief devices,
or
3.Fail to perform needed/required
maintenance on relief devices
Installation, Inspection, and
Maintenance
To undermine all the good efforts of a
design crew, simply …
1.Improperly install relief devices
2.Fail to regularly inspect relief devices,
or
3.Fail to perform needed/required
maintenance on relief devices
44/51
?? Reduced Inlet Piping
Anything wrong
here?
Reduced
Inlet Piping
?? Reduced Inlet Piping
Anything wrong
here?
Reduced
Inlet Piping
45/51
?? Plugged Bellows, Failed
Inspection, Maintenance
Bellows plugged
in spite of sign
Anything wrong
here?
Failed
Inspection
Program
Signs of
Maintenance
Issues
?? Plugged Bellows, Failed
Inspection, Maintenance
Bellows plugged
in spite of sign
Anything wrong
here?
Failed
Inspection
Program
Signs of
Maintenance
Issues
46/51
?? Discharges Pointing
Down
Anything wrong
here?
Anything wrong
here?
Discharges
Pointing Down
?? Discharges Pointing
Down
Anything wrong
here?
Anything wrong
here?
Discharges
Pointing Down
47/51
?? Long Moment Arm
Anything wrong
here?
Long
Moment Arm
?? Long Moment Arm
Anything wrong
here?
Long
Moment Arm
48/51
?? Will these bolts hold in a
relief event
Anything wrong
here?
Will these
bolts hold
in a
relief event?
?? Will these bolts hold in a
relief event
Anything wrong
here?
Will these
bolts hold
in a
relief event?
49/51
Mexico City Disaster
Major Contributing Cause:
Missing Safety Valve
Mexico City Disaster
Major Contributing Cause:
Missing Safety Valve
50/51
Summary
Pressure Relief
–Very Important ACTIVE safety element
–Connected intimately with Process Hazard
Analysis
–Requires diligence in design, equipment
selection, installation, inspection and
maintenance
Look forward to …
–Two-phase flow methodology/exercise
Summary
Pressure Relief
–Very Important ACTIVE safety element
–Connected intimately with Process Hazard
Analysis
–Requires diligence in design, equipment
selection, installation, inspection and
maintenance
Look forward to …
–Two-phase flow methodology/exercise
51/51
References
Crowl and Louvar–Chemical Process
Safety, Chapters 8 and 9
Ostrowski–Fundamentals of Pressure
Relief Devices
Sterling–Safety Valves: Practical
Design, Practices for Relief, and Valve
Sizing
References
Crowl and Louvar–Chemical Process
Safety, Chapters 8 and 9
Ostrowski–Fundamentals of Pressure
Relief Devices
Sterling–Safety Valves: Practical
Design, Practices for Relief, and Valve
Sizing
END OF
PRESENTATION
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