In
the manufacture of hydrogen through steam reforming of natural gas or naptha,several
waste gas streams are generated.The steam reforming process converts a
mixture of hydrocarbons and steam into hydrogen,methane,carbon dioxide,carbon
monoxide and water vapor in the presence of a catalyst.The hydrocarbon
feed and steam at a pressure of about 30-40 atm enter the primary reformer
at about 450 C and a reaction is initiated at 600 C,through combustion
of natural gas or naptha. The flue gases thus generated leave the reformer
at about 1000 C and energy is recovered from these gases by generating
high pressure superheated steam in a flue gas waste heat boiler.This boiler
is like a conventional waste heat boiler,consisting of multiple coils and
sometimes an air preheater.Sometimes low pressure steam in addition to
high pressure steam is also generated.Finned tubes may be used in the cooler
gas temperature regions of the boiler as the gas stream is clean. The flue
gas pressure is nearly atmospheric.The mixture of feed and steam mixture
is often preheated in this waste heat boiler.The high pressure saturated
steam generated in the reformed gas boiler is mixed with the saturated
steam generated in the flue gas boiler and the total steam is superheated
in the flue gas boiler.(it is easier to include superheaters,economizers
in the flue gas stream compared to the high pressure reformed gas stream).The
steam generated is used to drive steam turbines for auxilliary equipment
after generating electricity via a steam turbine.
The
tube side effluents from the primary reformer go the secondary reformer
before which preheated air is added.Combustion reactions occur and the
catalysts convert the methane partly to hydrogen.The effluent called reformed
gas and consisting of water vapor,hydrogen,carbon dioxide,carbon monoxide
and some methane and nitrogen,enter a waste heat boiler called Reformed
gas boiler. Click
here to see typical analysis of waste gas streams
.Gases are cooled from about
1000 C to 300-350 C.Since the gas pressure is high,fire tube boilers are
generally used,though water tube designs are available. Since the exit
gas temperature from the boiler is critical for reactions with catalysts
downstream,the exit gas temperature is controlled using internal or sometimes
external gas bypass system.A few bypass systems are designed such that
even in the event of the full opening of the bypass damper,the exit gas
temperature is limited to less than 900-1000 F and the downstream equipment
are unaffected.Note that the gas temperature leaving the bypass section
is typically the inlet gas temperature as there is generally no cooling
of the gas in the bypass section.
The
heat transfer coefficient with reformed gases is high,on the order of 5
to 7 times that with typical flue gases due to the presence of the hydrogen
and water vapor and also the high mass flow rate due to high gas pressure;
hence the heat flux on the steam side will be high and is often limited
to about 100,000 Btu/ft2h to avoid DNB concerns. Tube sheet
design is also given consideration due to this reason. Tube sheets are
protected by refractory and ferrules as shown,which are typically made
of Inconel 800 or ceramic materials.
Adequete
boiler water circulation is ensured with the help of an elevated steam
drum and external downcomers,risers so that the tube sheet and tubes are
protected.
Since
the gas stream contains hydrogen at high partial pressure,hydrogen embrittlement
and corrosion is a consideration in the selection of tube materials. Generally
T11 or T22 (chrome-moly) steels are used for boiler tubes.
Metal
dusting also occurs in carbanaceous atmospheres.It takes the form of pitting,thinning
and wastage.The alloy is turned into dust and hence the term.Ensuring
that the tube ,tube sheets operate at less than 800 F minimizes this concern.
The
cooled gases then enter a shift converter where conversion of carbon moxide
to dioxide takes place in the presence of catalysts;hydrogen is also formed.
The exothermic reaction raises the gas temperature to about 425 C.The gases
are cooled in a converted gas boiler or a series of boilers depending on
the % conversion of carbon monoxide.Gas temperature control is important
in these boilers,which are similar in design to the reformed gas boiler.The
gases then enter a methanator where traces of carbon monoxide and carbon
dioxide are converted to methane and water vapor.The methanator outlet
gas is cooled in a syn gas exchanger and condensate is removed.The gas
is then compressed to very high pressure,about 250-350 atm,and enters a
converter where nitrogen and hydogen interact to form ammonia,which is
a component of fertilizers.
The
scheme shown above may have several variations depending on the engineering
of the system.From heat recovery viewpoint,the flue gas and reformed gas
boilers are significant.In small hydrogen plants,the flue gas boiler and
reformed gas boilers may be built into a single package with a common steam
drum;see the author's book on waste heat boilers.
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