Saturday, 3 December 2011

Distillate/Diesel Hydrotreating

Introduction
Distillate or Diesel Hydrotreaters, also referred to as Hydrodesulfurization Units, remove organic sulfur, nitrogen, halide, oxygenate, and metals compounds from diesel boiling range feed.  Hydrotreaters achieve this by passing feed over a bed of hydrotreating catalyst in the presence of hydrogen and at high temperatures and relatively high pressures.   Organic Sulfur and Nitrogen Compounds must be removed from diesel product to reduce SOX and NOX emissions from diesel engines during combustion.  In the diesel hydrotreating process, organic sulfur, nitrogen, and oxygen compounds are converted to H2S, Ammonia, and Water, respectively. 
C4H9SH + H2 -> C4H10 + H2S
C5H5N + 5H2 -> C5H12 + NH3
C6OH +H2 -> C6H12+ H2O

Metal contaminants are trapped on the reactor catalyst surface, which in addition to coking, deactivates the catalyst overtime and necessitating catalyst change-out.  Because these reactions take place in the presence of hydrogen, hydrotreating also saturates olefin and aromatic compounds in the feed. 
Diesel Hydrotreater

Feed and Feed Pre-Heat
Diesel from numerous units in the refinery e.g. Crude/Vac, FCC, Coker, etc. are combined with makeup and recycle hydrogen.  The combined feed is directed to the feed preheat section of the plant where it is exchanged with hot reactor effluent to raise the mixture to optimum feed heater inlet temperature.  This decreases the duty (energy) requirement of the fired feed heater-saving on natural gas or fuel oil which fires the heater.  In the fired heater, the feed passes through the fired heater’s tubes where it is raised to the required reactor inlet temperature to promote the hydrotreating reactions, 300 to 400C in the unit depicted above. 
 
Reactor
The hydrotreating reactions are exothermic.  As a result, a temperature rise is observed across the reactor catalyst bed.  To prevent a runaway, or uncontrolled, extremely high temperature reactions in the catalyst bed, reactor bed temperatures are closely monitored.  A runaway results in extremely high temperatures that could potentially result in a serious safety hazard for refinery personnel as well as catalyst and equipment damage as temperatures exceed the specifications of the metallurgy of the reactor vessel.  The refiner has several handles to control the rate of reaction:  Feed Quality, H2/HC Ratio or H2 Makeup, Reactor Temperature, Recycle, Quench, LHSV, and Catalyst.
Feed Quality
Feed quality to the diesel hydrotreater, DHT, varies with the refinery’s current crude mix, the type of upstream unit feeding the diesel hydrotreater, and the operating mode of the upstream units.  Refinery process units do not operate in a vacuum-they are dependent on the operating mode of the entire refinery.  If the refinery is running sweet crudes, less that .5% sulfur, the amount of sulfur in the feed to a DHT will be much lower than when the refinery is running sour crude.  Another concern is the amount of crack stock in the feed to the unit. Cracked stock is product from a thermal or catalytic cracking unit like a delayed coker or FCC.  These units process the heavier cuts from the crude unit like gas oil and residue which contain more difficult to process sulfur, nitrogen organic compounds as well as a higher amount of metals. Diesel direct from the crude unit, referred to as straight run diesel, results in a much lower exotherm (temperature rise) across the reactor bed because 1)  it is derived direct from the lower sulfur portion of the crude mix and 2) it contains fewer olefinic , or unsaturated, straight-chain compounds.  Olefins react rapidly with hydrogen (to saturate), an exothermic reaction that results in a large heat release.   Another consideration is operation of the fractionation sections of the upstream units.  If the end point of the light cycle oil, LCO, from the FCC’s Main Column increases (meaning heavier material is drawn from the diesel/LCO draw from the column and sent to the DHT), a higher amount of more difficult to hydrotreat material will be sent to the DHT.
H2/HC Ratio
The desulfurization, denitrogenation, and deoxygenation reactions consume hydrogen.  Hydrogen, H2, also saturates olefins and aromatics and prevents coking or condensation of hydrocarbon on hydrotreating catalyst.  Think of coking essentially as hydrocarbons burning and leaving carbon residue on the active sites of the catalyst preventing catalyst from carrying out the required hydrotreating reactions or catalyst deactivation.  H2/HC ratio is the amount of Makeup+ Recycle Hydrogen divided by barrels of feed.  Hydrogen is a feed source for several units in the refinery.  Refineries are often H2 limited or do not have enough hydrogen to meet the needs of all H2 consumers.  Hydrogen is generated in the refinery’s Catalytic Reforming or Steam Methane Reforming Units or purchased from an outside provider.  Hydrogen is costly for the refinery to produce or purchase.  As such, the H2 to HC ratio must be optimized to not only meet the needs of the hydrotreating reactions and to maintain catalyst life but also to ensure profitability for the refinery.  To prevent waste of Hydrogen, Separator Hydrogen is recycled back to the feed of the hydrotreater in addition to normal H2 make-up.  Some refineries also cascade hydrogen purge from one hydrotreater to another if the hydrogen content is high enough to meet the units needs.
Reactor Temperature
Reactor Temperature is a variable in daily unit operation as well as long term catalyst activity monitoring.  Operations can control the heater coil outlet temperature of the furnace and quench, described below.  Several thermocouples are inserted throughout the catalyst bed to monitor catalyst activity and look for hot spots due to channeling and poor catalyst loading.  Poor distribution of hydrocarbon through the bed results from channeling   which leads to reactor internals damage or temperature runaway. 
The Weight Average Bed Temperature is used by unit engineers to monitor catalyst deactivation.  WABT increases SOR to EOR (Start of Run to End of Run) due to coking or metals deposition on catalyst. Operators should not operate the unit to WABT in daily operation.  Temperatures from individual thermocouples throughout the catalyst bed should be considered and monitored for hot spots.  Still, because of the distance between thermocouples, it is still possible to have undetected hot spots.
Recycle
Recycling hydrotreated product from the fractionation section back to the feed can also be used to control the severity of hydrotreating operation.  Recycling back the product reduces the amount of highly contaminated and thus highly reactive feed to the unit.  However, this also limits the capacity or the amount of feed that can be processed in the unit. 
Quench
Some Distillate Hydrotreaters have the option of directing hydrogen directly in between beds in multiple catalyst bed reactors.  This hydrogen serves as a means of cooling to the reactors in high severity operations as well as additional hydrogen for the treating reactions. 
LHSV
Liquid Hourly Space Velocity is the volumetric feed rate divided by catalyst volume.  Higher LHSV means a higher feed rate to the unit, means a greater amount of reactive material to the catalyst, leading to a greater temperature rise across the catalyst.  This also leads to earlier catalyst deactivation.
Catalyst
Hydrotreating Catalyst is typically made of Nickel-Molybdenum.  Catalyst is selected by the refinery to meet a variety of feed, product, and operating goals e.g. typical feed quality and desired operating severity, medium or Ultra Low Sulfur Diesel operating mode, and length of catalyst life.
Gas Separation
Effluent from the reactor passes through the feed effluent exchanger and enters a fin fan exchanger where the effluent is cooled to separator temperature, 35C per the above diagram.  Organic Chlorides combined with Ammonia from the denitrogenation reactions to for ammonium salts which could deposit on the tubes of the fin fan exchanger and, in addition to reduced cooling/heat transfer, cause lead to corrosion.  To prevent this, water is combined with the reactor effluent which washes the salts away.  Once the material is cooled, it enters the separator where the gas phase hydrogen and light end material (typically C1-C4) is separated or flashes off from the now liquid phase product.  This light end C1-C4 material comes from the small amount of hydrocracking that also occurs in addition to the hydrotreating reactions.  This number is small typically .4-.6 wt% of feed in most operations.  The separator sets the pressure for the unit.  Typically two pressure control schemes are used: 1) the Makeup hydrogen rate is maintained to set unit pressure while the HPS vent to the sour gas system floats or the HPS vent to the sour gas system is used to control pressure while make-up hydrogen floats.  Remember Hydrogen Partial pressure and pressure of a DHT are essentially synonymous as it makes the greatest contribution to the pressure of the unit. Products from the Separator are typically Recycle Hydrogen (Unless Once Through), Vent Gas to the Sour H2 System or Fuel Gas, Water if there is a water boot, and Liquid Hydrocarbon.  The Recycle Hydrogen in the diagram above is directed to an amine contactor to scrub for H2S and Ammonia before directing it to the recycle compressor suction to pressure the gas back to the feed or the reactor as quench.
Fractionation 
The liquid from the separator is directed to the unit’s fractionation section where products are prepared for downstream units or product blending.  The stripping column depicted above is total condensing meaning that no overhead product is drawn from the top of the tower other than light ends which are sent to the refinery’s gas plant.  This light end material is removed not only to rid diesel product from any dissolved H2S and ammonia but also to allow the diesel to meet other specifications like flash for blending.  There may also be a naphtha overhead product that is drawn from the overhead in partial condensing towers (reflux plus product draw).
In the drawing above, the stripping column is heated or reboiled by exchanging a portion of the bottoms material with hot oil or steam and returning that material to the bottom of the tower.  When feed enters the tower, lighter material vaporizes and rises through the trays of the column while the heavier material flows down the column.  Some valuable diesel product material is also vaporized and entrained with lighter material which exits the top of the column.  This vapor is cooled to liquid phase in a condenser, collected the overhead receiver.  Uncondensed light ends are vented to sour gas treatment and the heavier liquid is refluxed back to the column to improve separation.  Cooled refluxed higher distillate concentrated liquid flows down over the upper column trays and comes in contact with rising vapors. Due to vapor liquid equilibrium discussed in earlier posts, heavy material flows back down the column leading to product purification.  Light end material leaves the overhead drum and is directed to the refinery’s sour gas plant.  Product diesel is drawn from the tower bottoms and sent to tankage or blending.

Sunday, 14 August 2011

Refinery Overview

         The purpose of a refinery is to separate and upgrade crude oil to useful products like gasoline or diesel fuel.  In the diagram below, each block represents a refining technology that separates or reshapes the various crude oil components to be blended (mixed) in order to meet various product specs like octane for gasoline or sulfur content for diesel. 
                To understand what’s going on per a refinery flow diagram remember three things: 1) The crude enters the refinery through the Crude (Atmospheric) Column, 2) Any unit entitled Treating/Treater means sulfur/nitrogen/metals removal, 3)Any unit with Cracking in the title means breaking heavy material into lighter, more valuable products.  Given these rules of thumb and the unit glossary below you can understand the layout of any refinery.  For example, follow the heavy naphtha cut from the crude column (referred to as straight run naphtha because it comes directly from the crude unit) to a hydrotreater where organic sulfur and nitrogen are removed from the naphtha.  After hydrotreating, the naphtha goes to a catalytic reforming unit where it is reformed into higher octane material.  After reforming, the naphtha is directed to product blending where it is blended into the gasoline product pool.


 
Atmospheric Distillation
As we covered in the “Crash Course to Distillation” entry, the Crude Unit, also referred to as Atmospheric Column, is the first entry point for crude oil into the refinery.  In the Crude Unit, salts and other debris from the oil well or gained during transport are removed in the Desalters.  After desalting, the crude is heated to 700-800F in the Crude Furnace before entering the base of the Crude Column.  In the crude column, the crude is separated by distillation into various products: Fuel Gas, LPG, Naphthas, Kerosene/Jet Fuel, Distillate (Diesel), and Atmospheric Gas Oils.
Vacuum Distillation
Crude oil has a boiling range from -257.8F (boiling point of Methane) up to 1400-1500F.  The Crude Unit Furnace Outlet temperature is a maximum of 800 F; this means any 800-1500F range material cannot be vaporized and distilled in the Crude Unit.  Raising Crude Furnace outlet temperature to vaporize the entire boiling range of crude is impossible because these heavy components coke or polymerize (basically burn) before reaching their boiling points at atmospheric pressure.  Therefore, Atmospheric Gas Oil is directed to the Vacuum Tower, which operates under vacuum conditions (negative pressure), in order to distill heavy components without coking.  Typical Vac Tower products are Light Vacuum Gas Oil (LVGO-diesel range material), Heavy Vacuum Gas Oil (HVGO), and Vacuum Residue.
Gas Processing
Light components typically C4- and some naphtha from the crude units (and typically other units downstream of the Crude Tower) are directed to the Gas Processing Plant to separate these components into various light end products: fuel gas, LPG, butanes, and gasoline (naphtha).
Amine Treating
Many of the hydroprocessing and catalytic reforming processes have the byproduct hydrogen sulfide, H2S. H2S is a poisonous gas that is a danger to operating personnel as well as suppresses some refining unit operations.  As such, this gas is removed from refinery gas streams in an Amine Treating Unit.  Basically this unit works by allowing sour (H2S contaminated) gases to flow counter currently to amine rich caustic (basic) streams in an “Amine Contactor”.  The sour gas is essentially stripped of H2S which is carried away with the countercurrent caustic stream.
Merox Treating
In Merox Units, mercaptans, organic sulfur compounds in LPG, naphtha, and kerosene streams are removed.  First the feed is contacted with a countercurrent stream of caustic which captures the mercaptans.  The sweetened product stream then flows through a caustic settler to remove any remaining caustic followed by a salt bed to remove any water.  The caustic itself is then regenerated by contacting it with a liquid catalyst and oxygen to convert the mercaptans to disulfides and then later allowing them to settle out in a separator.
Claus Sulfur Plant
Sulfur Plants remove sulfur from H2S contaminated refinery streams by first burning the H2S and then sending it to a condenser which results in some elemental sulfur precipitating out.  In addition to elemental sulfur, SO2 , a combustion byproduct,  and unconverted H2S remain in the stream.  To complete the sulfur removal process, H2S and SO2 are passed over catalyst where they react to form elemental sulfur and water.
Hydrotreater
The purpose of a hydrotreater is to remove sulfur, nitrogen, oxygen compounds, organic halides (R-Cl), and metals compounds in order to 1) Prevent the poisoning (deactivation) of catalyst in downstream units and 2) meet environmental regulations for SOX and NOX.  Hydrotreaters work by passing hydrocarbon streams, e.g. naphtha, over a bed of catalyst in the presence of hydrogen. 
Isomerization
In isomerization, C4-C6 material is passed over a bed of catalyst in the presence of hydrogen.  The purpose of isomerization is to convert straight chain paraffins to branched paraffins which have higher octane for blending. 
Catalytic Reformer
Catalytic Reforming units accomplish two purposes: 1) increase the octane of naphtha feeds and 2) produce hydrogen to be used in other hydrogen consuming units in the refinery e.g. hydrotreaters. In fixed bed reformers, naphtha passes through multiple beds of reforming catalyst.  Several reactions occur that result in higher octane product molecules: straight chain paraffins become branched or form rings, naphthenes dehydrogenate to aromatics (generating hydrogen), and so on.  Octane increasing reactions compete with cracking reactions which consume hydrogen and reduce reformate yield.
Hydrocracker
Hydrocrackers provide both contaminant removal and upgrading of lower value products.  In the refinery above, heavy vacuum gas oil is directed to the hydrocracker where it typically first encounters a bed of hydrotreating catalyst where sulfur, nitrogen, oxygen, organic halide compounds and well as metals are removed in the presence of hydrogen.  After the treating section, several beds of hydrocracking catalyst follow in order to crack the treated HVGO to lighter material.  Hydrocrackers operate at incredibly high temperatures and pressures and are major consumers of hydrogen in refineries.
Alkylation
Alkylation Units allow the refiner to upgrade light end material to gasoline range material.  In the presence of Hydrofluoric Acid or Sulfuric Acid, isobutane is reacted with C3-C4 olefins to form C7-C8 naphtha range products.   
FCC Feed Treater
FCC Catalyst is very susceptible to metals poisoning, especially vanadium.  To prevent deactivation of FCC catalyst as well as removing sulfur and nitrogen to meet environmental specs, FCC feed is treated in a FCC Feed Treater.  The Cat Feed Hydrotreater works much like other hydrotreaters, gas oils pass through a series of catalyst beds at elevated temperatures and in the presence of hydrogen.
Fluid Catalytic Cracker (FCC)
FCC Units are referred to as the heart of the refinery because they are able to convert heavy gas oil material to more valuable gasoline, kerosene, and distillate products.  It does this by cracking the gas oil in the presence of a catalyst that selects for increased gasoline and distillate yields. FCC’s are considered the more complicated units in the refinery because instead of a fixed bed, the unit’s catalyst is fluidized and circulated throughout the reactor and regenerator sections.    
Delayed Coker
Delayed Coking is one of the thermal cracking (heat only-no catalyst) processes in the refinery.  Vacuum Tower Resid is heated in a furnace at incredibly high temperatures, typically 1000F, before entering large coke drums where the resid is allowed to coke or polymerize (burn).  Any material not burned in the drums rise as vapors and flow to the base of the coker fractionator where they are distilled to gas oil and lighter products.  The key to coking is that resid material is prevented from coking in the furnace tubes by achieving high velocities through the furnace tubes.  Once the drums are filled with coke, they are taken off line and the coke is cut out of the drums and sold as product depending on the grade of coke.
Asphalt Blowing
The Asphalt used to pave roads comes from the heavy vacuum residual material from the bottom of the vacuum tower.  This reside serves as a binder and is mixed with gravel and used in road construction.  Roads and highways face the stress of daily car use as well as changing weather conditions.  As such, the material used to pave roads must meet certain viscosity and strength tests in order to be used in asphalt.  To meet highway specification, asphalt is blown by exposing it to oxygen and heat in order to meet required viscosity specs in an Asphalt Blowing Unit.

Top US Refiners by Name Plate Capacity

The top ten US Refiners by name plate capacity are Exxon, ConocoPhillips, Valero, BP, Marathon, Chevron, Koch Industries (Flint Hills Resources), PDV America (Citgo), Motiva Enterprises (Shell/Saudi Refining), and Sunoco.  The top ten refiners control 64.4% of the refining capacity in the United States.  The top two companies, Exxon and ConocoPhillips, own 10.17% and 9.8%, respectively.

Rank
Corporation
 BBLS/Day 
% US Capacity
1
EXXON MOBIL CORP
        1,855,240
10.17%
2
CONOCOPHILLIPS
        1,787,000
9.80%
3
VALERO ENERGY CORP
        1,682,300
9.22%
4
BP PLC
        1,302,350
7.14%
5
MARATHON OIL CORP
        1,142,000
6.26%
6
CHEVRON CORP
        1,027,271
5.63%
7
KOCH INDUSTRIES INC
           771,578
4.23%
8
PDV AMERICA INC
           757,800
4.16%
9
MOTIVA ENTERPRISES LLC
           753,500
4.13%
10
SUNOCO INC
           673,000
3.69%
11
TESORO CORP
           657,300
3.60%
12
WRB REFINING LLC
           508,000
2.79%
13
HOVENSA LLC
           500,000
2.74%
14
ROYAL DUTCH/SHELL GROUP
           436,400
2.39%
15
DELAWARE CITY REFINING CO LLC
           342,200
1.88%
16
DEER PARK REFINING LTD PTNRSHP
           327,000
1.79%
17
HOLLY CORP
           285,350
1.56%
18
ACCESS INDUSTRIES
           280,390
1.54%
19
TOTAL SA
           232,000
1.27%
20
ALON ISRAEL OIL COMPANY LTD
           231,500
1.27%
21
WESTERN REFINING INC.
           226,200
1.24%
22
CHALMETTE REFINING LLC
           192,500
1.06%
23
FRONTIER OIL REFINING & MKTG
           185,000
1.01%
24
MURPHY OIL CORP
           159,300
0.87%
25
HUSKY ENERGY INC
           155,000
0.85%
26
CHS INC
           145,100
0.80%
27
BP HUSKY REFINING LLC
           131,400
0.72%
28
ERGON INC
           118,000
0.65%
29
CVR ENERGY INC
           115,700
0.63%
30
SUNCOR ENERGY INC
           103,000
0.56%
31
PETROLEO BRASILEIRO SA
           100,000
0.55%
32
SINCLAIR OIL CORP
             98,500
0.54%
33
NUSTAR ENERGY LP
             98,000
0.54%
34
CALUMET LUBRICANTS CO
             78,320
0.43%
35
TRANSWORLD OIL USA INC
             78,000
0.43%
36
ARCTIC SLOPE REGIONAL CORP
             74,700
0.41%
37
NORTHERN TIER ENERGY LLC
             74,000
0.41%
38
GARY WILLIAMS CO
             70,000
0.38%
39
UNITED REFINING INC
             65,000
0.36%
40
DELEK GROUP LTD
             60,000
0.33%
41
PLACID OIL CO
             57,000
0.31%
42
HUNT CONSLD INC
             47,000
0.26%
43
COMPAGNIE NATIONALE A  PORTEFEUILLE
             38,800
0.21%
44
FJ MANAGEMENT INC
             29,400
0.16%
45
COUNTRYMARK COOP INC
             26,500
0.15%
46
KERN OIL & REFINING CO
             26,000
0.14%
47
SAN JOAQUIN REFINING CO INC
             15,000
0.08%
48
AGE REFINING & MARKETING INC
             14,021
0.08%
49
WYOMING REFINING CO
             14,000
0.08%
50
SILVER EAGLE REFINING INC
             13,250
0.07%
51
VENTURA REFINING AND TRANSMISSION LLC
             12,000
0.07%
52
AMERICAN REFINING GROUP INC
             10,000
0.05%
53
CONNACHER OIL & GAS LTD
             10,000
0.05%
54
GREKA ENERGY
               9,500
0.05%
55
WORLD OIL CO
               8,500
0.05%
56
MARTIN RESOURCE MANAGEMENT GRP
               7,500
0.04%
57
MIDSOUTH ENERGY LLC
               5,500
0.03%
58
GOODWAY REFINING LLC
               4,100
0.02%
59
GARCO ENERGY LLC
               3,600
0.02%
60
OIL HOLDING INC
               2,800
0.02%
61
FORELAND REFINING CORP
               2,000
0.01%

TOTAL CAPACITY
      18,236,370