Post on 11-Jul-2018
In The Name OF God
Hampa Energy Engineering &Hampa Energy Engineering &Hampa Energy Engineering & Hampa Energy Engineering & Design CompanyDesign Company
1www.hedcoint.comwww.hedcoint.com
IntroductionAmmonia plantsMethanol plantsHydrogen PlantsHydrogen PlantsOther plants
2www.hedcoint.com
A Brief historical ReviewGreater capacity
3300 mtpd 20 rows with a total of 960 tube
Improve efficiency
3www.hedcoint.com
Reformer TypesTop Fired
Side FiredSide Fired
Terraced Wall
4www.hedcoint.com
Design ParametersFunctionFeed
l
Heat FluxPressure Drop
FuelsType Pressure
CatalystTubes
PressureExit TemperatureInlet Temperature
BurnersFlow distributionH RInlet Temperature
Steam/Carbon Ratio
Heat Recovery
5www.hedcoint.com
Function
6www.hedcoint.com
FeedNatural gas
PropanePropane
LPG
Butane
Naphthap
7www.hedcoint.com
FuelsNatural gas
Distillate fuelsDistillate fuels
8www.hedcoint.com
Type : Top Fired The highest flue gas temperature when the intube process
gas temperature is lowestgas temperature is lowest
The lowest flue gas temperature when the intube process
i hi hgas temperature is highest
Uniform tubewall temperature over the length of the tube
Inherently stable furnace operation
9www.hedcoint.com
PressureThe reforming reaction equilibrium is favored by low
pressurepressure
The shift reaction equilibrium is independent of pressure
Product hydrogen pressure requirement (down stream)
10www.hedcoint.com
Exit TemperatureLower temperatures give insufficient conversion
Higher temperature increase metallurgical requirementsHigher temperature increase metallurgical requirements
Gas exit temperature typically runs between 800 to 900 °C
11www.hedcoint.com
Inlet TemperatureThe reforming reaction rate becomes significant at about 540 °C
Higher reformer inlet temperature decrease the number of tubes, g p ,
the size of the furnace and fuel
Higher reformer inlet temperature decrease the steamHigher reformer inlet temperature decrease the steam
generation from WHR
M ll i l li iMetallurgical limits
Optimum reformer inlet temperature 560 °C
12www.hedcoint.com
Steam/Carbon RatioSufficient steam to eliminate carbon formation
If proper catalyst is chosen 3 steam to carbon ratio isIf proper catalyst is chosen, 3 steam to carbon ratio is
applicable
13www.hedcoint.com
Heat FluxA low heat flux provide extra catalyst volume and lower
tubewall temperaturetubewall temperature
A high heat flux has the advantage of reducing the number
f bof tubes
20000 to 28000 Btu/hr-ft2
14www.hedcoint.com
Pressure DropLegnth of tubes
Tube diameterTube diameter
Catalyst selection
Approximately 3 Bar
15www.hedcoint.com
CatalystReaction conversion
Nickel-alkaliNickel-alkali
shape
Catalyst pressure drop
Shapep
Key aspect of catalyst : formulation & shape
16www.hedcoint.com
TubesTemperature condition : 850 to 920°CInside tube diameter : 4 to 5 in
Better heat transfer and cooler walls for lower IDBetter heat transfer and cooler walls for lower IDHigher pressure drop for lower IDMore required tubes for lower ID
T b l th tTube length : 12 to 13 mLonger tube reduces the flue gas exit temperatureLonger tube increases pressure drop Longer tube decreases required tube
Tube pitch : 2 to 3 tube diameterLane spacing : 1.8 to 2.4 mLane spacing : 1.8 to 2.4 m
17www.hedcoint.com
BurnersUniform heat release
One burner for every 2 5 to 3 5 tubes is a good designOne burner for every 2.5 to 3.5 tubes is a good design
practice
18www.hedcoint.com
Flow distributionSymmetrical piping design
Detailed pressure drop calculationDetailed pressure drop calculation
Properly designed flue gas tunnel
Properly fan design
19www.hedcoint.com
Heat RecoveryInlet temperature of flue gas approximately 900°C
Reformer mixed feed preheater steam superheater steamReformer mixed feed preheater, steam superheater, steam
generation, boiler feedwater heater, feed heater,
b i i hcombustion air preheater
Exit temperature of flue gas approximately 200 °C
20www.hedcoint.com
Overall view
21www.hedcoint.com
Forced fan
22www.hedcoint.com
Air Preheater
23www.hedcoint.com
Air ducts
24www.hedcoint.com
Fuel
25www.hedcoint.com
Radiant box
26www.hedcoint.com
Convection box
27www.hedcoint.com
Heat recovery
28www.hedcoint.com
Induced fan and stack
29www.hedcoint.com
Feed
30www.hedcoint.com
Catalyst tubes
31www.hedcoint.com
Tube supports
32www.hedcoint.com
Radiant SectionConsiderations
Variation of heat demand from inlet to outletUniformity of heat distribution along the length of the furnaceUniformity of heat distribution along the length of the furnaceUniformity of circumferential heat flux Flow distribution in reactors for lowest turn downA d iti l h t fl i th f fi bAverage and critical heat flux in the reformer firebox
CFD modeling
33www.hedcoint.com
Casing Design
Design Temp 80 °C
Designed for deflection to minimize refractory damage
N d b i i h iNeeds to be an air tight construction
Resistant to wind loads and other imposed loads
34
Reformer TubesCreep
Bending stress
Thermal cycles
El iElongation
35www.hedcoint.com
Reformer TubesTube material
Tube Strength
36www.hedcoint.com
Catalyst DevelopmentControl tube wall temperature
Achieved the required conversionAchieved the required conversion
Have a low and stable pressure drop
Avoid carbon formation
Operation over a larger feed compositionp g p
37www.hedcoint.com
Catalyst shapeActivity
Heat Transfer CoefficientHeat Transfer Coefficient
Pressure Drop
38www.hedcoint.com
RefractoryCeramic fiber
ModuleBl kBlanket
CastBrickBrick
39www.hedcoint.com
Transfer lineDesign ConditionsProblems
E iErosionPipe failureCondensationCondensation
RefractoryDesignDesignAnchoring
40www.hedcoint.com
Sample Reformer Process Requirements:
(2050 TPD AMMONIA PRIMARY(2050 TPD AMMONIA PRIMARY REFORMER)
41www.hedcoint.com
Process Gas174 ton/h520 °C39 Bar
Super Heated SteamSuper Heated Steam353 ton/h510 °C5117 Bar
Process Air Heater/h105 ton/h
540 °C37 Bar37 Bar
42www.hedcoint.com
HEDCO Specifications For :Specifications For :
2050 TPD AMMONIAPRIMARY REFORMER
43www.hedcoint.com
C l T bCatalyst Tubes48 tube @ 7 rowID 114 3ID = 114.3Effective Tube Length : 12.5 mInlet Temperature : 520Inlet Temperature : 520Outlet Temperature : 800Design Temperature : 920Max Wall Thickness : 890Thickness : 12 mmDesign Pressure : 41 BarMax Pressure Drop : 3 BarR S iRow Spacing : 2.1 m
44www.hedcoint.com
Catalyst Tubes
capacitytotal
tubes rowtubes in
row riser ID Thk Eff Lengthcapacity tubes row row riser ID Thk Eff LengthKellogg-Ghadir 187 336 6 56 6 110 12 11.8
Linde-LindeRazi 132 235 5 47 102.2 7.9 10.9
Linde-Lordegan 174 336 7 48 114.3 12 12.5
KTI-Shiraz 174 320 8 40 114.3 10.2 12.6HEDCO D i 174 336 8 42 114 3 12 12 5Design 174 336 8 42 114.3 12 12.5
45www.hedcoint.com
Tube Wall Temperature
it I TOut
TDes
TMax
TID f capacity InTemp Temp Temp Temp surface
Kellogg-Ghadir 187 620 812 924 889 1370
Linde Razi 132 620 775 845 817 822 4Linde-Razi 132 620 775 845 817 822.4
Linde-Lordegan 174 520 800 920 824 1507
KTI-Shiraz 174 520 800 914 889 1447 8KTI-Shiraz 174 520 800 914 889 1447.8
HEDCO Design 174 520 800 920 889 1507.4
46www.hedcoint.com
BurnersArch Burners
Inner burners Number : 12 @ 7 row = 84Inner burners Duty = 2 MVO t B N b @Outer Burners Number: 12 @ 2 row = 24 Outer Burners Duty = 1.73
Tunnel BurnersTunnel BurnersTunnel Burners Number = 8 @ 1 rowTunnel Burners Duty = 0.53 MWy 53
Auxiliary BurnersAuxiliary Burners Number : 10 @ 5 rowAuxiliary Burners Duty = 4.26 MW
47www.hedcoint.com
Burners
capacity Arch burner Auxiliary Tunnel N D t N D t N D t No Duty No Duty No Duty
Kellogg-Ghadir 187 80/32 1.8/1.17 19 1.44 7 0.63
132 60/30 1 42/85 6 2 05Linde-Razi 132 60/30 1.42./85 6 2.05 Linde-Lordegan 174 72/24 2.3/1.38 6 7.8
KTI-Shiraz 174 84/24 16 9 HEDCO Design 174 84/24 2/1.38 10 4.25 8 0.53
48www.hedcoint.com
49www.hedcoint.com
50www.hedcoint.com
51www.hedcoint.com
Thank YouThank You
52www.hedcoint.com