Title of Invention

PROCESS AND APPARATUS FOR CONVERTING CARBONACEOUS MATERIAL TO ENERGETIC GASES

Abstract A process and apparatus for producing a synthesis gas for use as a gaseous fuel or as feed into a Fischer-Tropsch reactor to produce a liquid fuel in a substantially self sustaining process. In one embodiment, a slurry of carbonaceous material in water, and hydrogen from an internal source, are fed into a hydro-gasification reactor to generate methane rich producer gases which are fed in to a steam pyrolytic reformer to generate synthesis gas comprising hydrogen and carbon monoxide. A portion of the hydrogen is used as the internal hydrogen source. The remaining synthesis gas is either used as fuel to produce electricity and/or process heat or is fed into a Fischer-Tropsch reactor to produce liquid fuel. In another embodiment of the invention, carbonaceous material can be heated simultaneously in the presence of both hydrogen and steam to undergo steam pyrolysis and hydro-gasification in a single step.
Full Text

CROSS-REFERENCE TO RELATED APPLICATION
This application is a continuation-in-part of, and claims the benefit of, International
Application PCT/US03/03489, herein incorporated by reference, with an international
filing date of February 4, 2003, published in English under PCT Article 21 (2), which
claims priority to U.S. Provisional Patent Application Serial No. 60/355,405, filed
February 5, 2002.
BACKGROUND OF THE INVENTION
Field of the Invention
The field of the invention is the synthesis of transportation fuel from carbonaceous feed
stocks. In particular, the invention relates to process and apparatus for converting
carbonaceous material to energetic gases.
Description of Related Art
There is a need to identify new sources of chemical energy and methods for its conversion
into alternative transportation fuels, driven by many concerns including environmental,
health, safety issues, and the inevitable future scarcity of petroleum-based fuel supplies.
The number of internal combustion engine fueled vehicles worldwide continues to grow,
particularly in the midrange of developing countries. The worldwide vehicle population
outside the U.S., which mainly uses diesel fuel, is growing faster than inside the U.S. This
situation may change as more fuel-efficient vehicles, using hybrid and/or diesel engine
technologies, are introduced to reduce both fuel consumption and overall emissions. Since
the resources for the production of petroleum-based fuels are being depleted, dependency
on petroleum will become a major problem unless non-petroleum alternative fuels, in
particular clean-burning synthetic diesel fuels, are developed. Moreover, normal
combustion of petroleum-based fuels in conventional engines can cause serious
environmental pollution unless strict methods of exhaust emission


control are used. A clean burning synthetic diesel fuel can help reduce the
emissions from diesel engines.
The production of clean-burning transportation fuels requires either
the reformulation of existing petroleum-based fuels or the discovery of new
methods for power production or fuel synthesis from unused materials. There
are many sources available, derived from either renewable organic or waste
carbonaceous materials. Utilizing carbonaceous waste to produce synthetic
fuels is an economically viable method since the input feed stock is already
considered of little value, discarded as waste, and disposal is often polluting.
Liquid transportation fuels have inherent advantages over gaseous
fuels, having higher energy densities than gaseous fuels at the same pressure
and temperature. Liquid fuels can be stored at atmospheric or low pressures
whereas to achieve liquid fuel energy densities, a gaseous fuel would have to
be stored in a tank on a vehicle at high pressures that can be a safety
concern in the case of leaks or sudden rupture. The distribution of liquid fuels
is much easier than gaseous fuels, using simple pumps and pipelines. The
liquid fueling infrastructure of the existing transportation sector ensures easy
integration into the existing market of any production of clean-burning
synthetic liquid transportation fuels.
The availability of clean-burning liquid transportation fuels is a
national priority. Producing synthesis gases cieanly and efficiently from
carbonaceous sources, that can be subjected to a Fischer-Tropsch process to
produce clean and valuable synthetic gasoline and diesel fuels, will benefit
both the transportation sector and the health of society. Such a process
allows for the application of current state-of-art engine exhaust after-treatment
methods for NOx reduction, removal of toxic particulates present in diesel
engine exhaust, and the reduction of normal combustion product pollutants,
current\y accomplished by catalysts that are poisoned quickly by any sulfur
present, as is the case in ordinary stocks of petroleum derived diesel fuel,
reducing the catalyst efficiency. Typically, Fischer-Tropsch liquid fueis,


produced from biomass derived synthesis gases, are sulfur-free, aromatic
free, and in the case of synthetic diesel fuel have an ultrahigh cetane value.
Biomass material is the most commonly processed carbonaceous
waste feed stock used to produce renewable fuels. Waste plastic, rubber,
manure, crop residues, forestry, tree and grass cuttings and biosolids from
waste water (sewage) treatment are also candidate feed stocks for conversion
processes. Biomass feed stocks can be converted to produce electricity,
heat, valuable chemicals or fuels. California tops the nation in the use and
development of several biomass utilization technologies. Each year in
California, more than 45 million tons of municipal solid waste is discarded for
treatment by waste management facilities. Approximately half this waste
ends up in landfills. For example, in just the Riverside County, California
area, it is estimated that about 4000 tons of waste wood are disposed of per
day. According to other estimates, over 100,000 tons of biomass per day are
dumped into landfills in the Riverside County collection area. This municipal
waste comprises about 30% waste paper or cardboard, 40% organic (green
and food) waste, and 30% combinations of wood, paper, plastic and metal
waste. The carbonaceous components of this waste material have chemical
energy that could be used to reduce the need for other energy sources if it
can be converted into a clean-burning fuel. These waste sources of
carbonaceous material are not the only sources available. While many
existing carbonaceous waste materials, such as paper, can be sorted, reused
and recycled, for other materials, the waste producer would not need to pay a
tipping fee, if the waste were to be delivered directly to a conversion facility. A
tipping fee, presently at $30-$35 per ton, is usually charged by the waste
management agency to offset disposal costs. Consequently not only can
disposal costs be reduced by transporting the waste to a waste-to-synthetic
fuels processing plant, but additional waste would be made available because
of the lowered cost of disposal.


The burning of wood in a wood stove is an example of using
biomass to produce heat energy. Unfortunately, the open burning the
biomass waste to obtain energy and heat is not a clean and efficient method
to utilize the calorific value. Today, many new ways of utilizing carbonaceous
waste are being discovered. For example, one way is to produce synthetic
liquid transportation fuels, and another way is to produce energetic gases for
conversion into electricity.
Using fuels from renewable biomass sources can actually decrease
the net accumulation of greenhouse gases, such as carbon dioxide, while
providing clean, efficient energy for transportation. One of the principal
benefits of co-production of synthetic liquid fuels from biomass sources is that
it can provide a storable transportation fuel while reducing the effects of
greenhouse gases contributing to global warming. In the future, these
co-production processes could provide clean-burning fuels for a renewable
fuel economy that could be sustained continuously.
A number of processes exist to convert coal and other
carbonaceous materials to clean-burning transportation fuels, but they tend to
be too expensive to compete on the market with petroleum-based fuels, or
they produce volatile fuels, such as methanol and ethanol that have vapor
pressure values too high for use in high pollution areas, such as the Southern
California air-basin, without legislative exemption from clean air regulations.
An example of the latter process is the Hynol Methanol Process, which uses
hydro-gasification and steam reformer reactors to synthesize methanol using
a co-feed of solid carbonaceous materials and natural gas, and which has a
demonstrated carbon conversion efficiency of >85% in bench-scale
demonstrations.
The need to identify new resources and methods for the production
of transportation fuels requires not only investigating improvements in ways to
produce current petroleum-based fuels but also research into new methods
for the synthesis of functionally equivalent alternative fuels obtained using


resources and methods that are not in use today. The production of synthetic
liquid fuels from carbonaceous materials such as waste organic materials is
one way to solve these problems. The utilization of carbonaceous waste
materials to produce synthetic fuels can be considered a feasible method of
obtaining new resources for fuel production since the material feed stock is
already considered a waste, without value and often it's disposal creates
additional sources of environmental pollution.
Summary of the Invention
The present invention makes use of steam pyrolysis, hydro-
gasification and steam reformation to produce a synthesis gas that can be
converted into a synthetic paraffinic fuel, preferably a diesel fuel, although
synthetic gasolines and jet propulsion fuels can also be made, using a
Fischer-Tropsch paraffin fuel synthesis reactor. Alternatively, the synthesis
gas may be used in a co-generated power conversion and process heat
system. The present invention provides comprehensive equilibrium thermo-
chemical analyses for a general class of co-production processes for the
synthesis of clean-burning liquid transportation fuels, thermal process energy
and electric power generation from feeds of coal, or other carbonaceous
materials, and liquid water. It enables a unique design, efficiency of operation
and comprehensive analysis of coal, or any other carbonaceous feed
materials to co-produced fuel, power and heat systems.
In one embodiment, the invention provides separate steam
pyrolysis, hydro-gasification, and steam reformer reactors in a process for
producing a synthesis gas for use as a gaseous fuel or as feed into a Fischer-
Tropsch reactor to produce a liquid paraffinic fuel, recycled water and sensible
heat, in a substantially self-sustaining process. A slurry of particles of
carbonaceous material suspended in liquid water, and hydrogen from an
internal source, are fed into a steam generator for pyrolysis and hydro-
gasification reactor under conditions whereby super-heated steam, methane,
carbon dioxide and carbon monoxide are generated and fed into a steam


reformer under conditions whereby synthesis gas comprising primarily of
hydrogen and carbon monoxide are generated. Using a hydrogen separation
filter for purification, a portion of the hydrogen generated by the steam
reformer is fed into the hydro-gasification reactor as the hydrogen from an
internal source. The remaining synthesis gas generated by the steam
reformer is either used as fuel for a gaseous fueled engine or gas turbine to
produce electricity and process heat, or is fed into a Fischer-Tropsch fuel
synthesis reactor under conditions to produce a liquid fuel, and recycled
water. The correct stoichiometric ratio of hydrogen to carbon monoxide
molecules fed into the Fischer-Tropsch fuel synthesis reactor, is controlled by
the water to carbon ratio in the feed stocks. Molten salt loops are used to
transfer heat from the exothermic hydro-gasification reactor (and from the
exothermic Fischer-Tropsch reactor if liquid fuel is produced) to the
endothermic steam generator for pyrolysis and the steam reformer reactor
vessels.
In particular, this embodiment provides the following features.
1) A general purpose solid carbonaceous material feed system that
can accept arbitrary combinations of coal, urban and agricultural biomass,
and municipal solid waste for hydro-gasification.
2) A first stage, steam generator for pyrolysis and hydro-
gasification unit.
3) A steam reformer as a second stage reactor to produce
hydrogen rich synthesis gas from the output of the first stage steam generator
for pyrolysis and hydro-gasification unit. The molal steam to carbon ratio is
maintained as necessary to bring the chemical reactions close to equilibrium;
4) Either (a) a Fischer-Tropsch (synthesis gas-to-liquid) fuel
synthesizer as a third and final stage reactor to convert the synthesis gas from
the steam reformer into a sulfur-free clean-burning liquid transportation fuel,


and recycled water or (b) use of generated synthesis gas as fuel for process
heat and/or in a fuel engine or gas turbine that can generate electricity;
5) Three thermo-chemical process reactors are operated to
produce nearly pure paraffinic hydrocarbon liquids (similar to petroleum
derived diesel fuels) and wax-like compounds (similar to petroleum derived
USP paraffinic jellies, which can be further refined into more diesel-like fuels
using conventional methods) from carbonaceous feed stocks (such as waste
wood) in a continuous self-sustainable fashion without the need for additional
fuels or external energy sources. The reactor configurations can also be
optimized for the production of other synthetic fuels, such as dimethyl ether (a
fuel similar to propane, that can be used as a transportation fuel in diesel
engines and gas turbines) and gaseous fuel grade hydrogen (a fuel that can
be used in engines and turbines, and if purified to remove carbon monoxide,
as an electrochemical fuel in a fuel cell), as well as energetic synthesis gases
for combined cycle power conversion and electric power production.
In another embodiment, a process is provided for converting
carbonaceous material to energetic gases by combining two separate
processes, steam pyrolysis and hydro-gasification, into a single step. The
process involves simultaneously heating carbonaceous material in the
presence of both hydrogen and steam at a temperature and pressure
sufficient to generate methane and carbon monoxide rich producer gases.
The process can be carried out on biomass, municipal waste, wood, synthetic
and natural polymers such as plastics and rubbers, and other carbonaceous
materials.
One of the advantages of combining steam pyrolysis and
hydro-gasification into a single step is the production of hydrocarbon gases
from carbonaceous material at rates much greater than the rates achievable
by hydro-gasification alone. Another advantage is the use of more compact
hydro-gasification reactors, with shorter residence times, than systems
without steam pyrolysis.


The fundamental advantages of this invention, over what was
achievable with the prior art, are: (a) energy efficient (>85%) methane
production from the available carbon in the carbonaceous feed stock using
steam pyrolysis to activate the carbon and hydrogen gas as the sole initiating
reactant, in contradistinction to partial oxidative gasification usually requiring
an additional energy intensive air separation system to provide the necessary
oxygen; (b) chemically self-sustained operation of the first stage hydro-
gasification reactor by feeding-back surplus hydrogen gas produced in the
second stage methane steam reformer reactor; (c) energy efficient synthesis
of clean-burning transportation fuels using the effluent gases from the steam
reformer, such as: (i) paraffinic compounds using a third stage Fischer-
Tropsch fuel synthesis reactor, (ii) dimethyl ether synthesis using a third stage
synthesis reactor, and (iii) hydrogen production using a hydrogen separation
and/or purification filter without the need for a third stage fuel synthesis
reactor; (d) thermally self-sustained operation of all reactors by effective
management of thermal and chemical energy using combinations of molten
salt or water/steam heat transfer fluids, combustion of product energetic
gases to start and maintain process temperatures, recovered process heat for
the generation of electric power, without the need for additional fuels and
external energy sources; (e) significantly reduced airborne emissions from all
enclosed processes reactors and/or synthesis gas combustors when
compared to direct naturally aspirated combustion (usually known as open
incineration) of the carbonaceous feed materials; and f) the ability to capture
all gaseous carbon dioxide effluent from process reactors or intra-process
synthesis gas combustors for sequestration and/or chemical conversion into
condensed phase compounds using conventional technologies.
These novel configurations of the process reactors have the
capability to improve the overall efficiency of energy utilization for
carbonaceous material conversion in a co-production plant for synthetic fuels,
chemicals and energy.


BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a flow diagram showing the overall modeling of one
embodiment of the present invention;
Figure 2 is a graph showing a plot of carbon conversion vs. H2 /C
and H2O/C ratios at 800°C and 30 atm. in HPR;
Figure 3 is a graph showing a plot of CH4/C feed ratio vs. H2/C
andH2O/C ratios at 800°C and 30 atm. in HPR;
Figure 4 is a graph showing a plot of CO2/C feed ratio vs. H2/C
andH2O/C ratio sat 800°C and 30 atm. in HPR;
Figure 5 is a graph showing a plot of CO/ C feed ratio vs. H2/Cand
H2O/C ratios at 800°C and 30 atm. in HPR;
Figure 6 is a graph showing the effects of Temperature and
Pressure conditions on CO2/H ration the hydro-gasifier reactor (HGR) at fixed
feed of 2.629 moles of H2 and 0.0657 moles of H2O per mole of C;
Figure 7 is a graph showing the effect of Temperature and Pressure
conditions on CH4/H ratio in the HGR at fixed feed of 2.629 moles of H2 and
0.0657 moles of H2O per mole of C;
Figure 8 is a graph showing the effect of Temperature and Pressure
conditions on H2/C ratio in the HGR at fixed feed of 2.629 moles of H2 and
0.0657 moles of H2O per mole of C;
Figure 9 is a graph showing the effect of Temperature and Pressure
conditions on CO/H in the HGR at fixed feed of 2.629 moles of H2 and
0.0657moles of H2O per mole of C;
Figure 10 is a graph showing the effect of input H2O/C ratio on
steam reformer (SPR) performance measure by the net H2/CO ratio after H2
recycling for the HGR at 1000°C and 30 atm;


Figure 11 is a graph showing the effect of changing the input H2O/C
ratio on SPR products, CO, CO2 and CH4 in the SPR at 1000°C and 30 atm;
Figure 12 is a graph showing the effect of Temperature and
Pressure conditions on H2/CO ratio in the SPR (2.76 moles of H2O/mole of C
added to the SPR);
Figure 13 is a graph showing the effect of Temperature and
Pressure conditions on CH4/C ratio in the SPR (2.76 moles of H2O/mole of C
added to the SPR);
Figure 14 is a diagram showing the Mass Flow Schematic of
Biomass Hydro-gasification for production of Fischer-Tropsch paraffin fuels;
Figure 15 is a diagram showing the Molal Flow Schematic of
Biomass Hydro-gasification for production of Fischer-Tropsch paraffin fuels;
Figure 16 is a diagram showing the Thermal Energy Management
Schematic of Biomass Hydro-gasification for production of Fischer-Tropsch
paraffin fuels;
Figure 17 is a diagram showing the Water/Steam Flow Schematic
of Biomass Hydro-gasification for production of Fischer-Tropsch paraffin fuels;
Figure 18 is a diagram showing Molten Salt Flow Schematic of
Biomass Hydro-gasification for production of Fischer-Tropsch paraffin fuels;
Figure 19 is a diagram showing Mass Flow Schematic of Biomass
Hydro-gasification for production of dimethyl ether;
Figure 20 is a diagram showing Mole Flow Schematic of Biomass
Hydro-gasification for production of dimethyl ether;
Figure 21 is a diagram showing Thermal Energy Management
Schematic of Biomass Hydro-gasification for production of dimethyl ether;


Figure 22 is a diagram showing Water/Steam Flow Schematic of
Biomass Hydro-gasification for production of dimethyl ether;
Figure 23 is a diagram showing Molten Salt Flow Schematic of
Biomass Hydro-gasification for production of dimethyl ether;
Figure 24 is a diagram showing Mass Flow Schematic of Biomass
Hydro-gasification for production of gaseous hydrogen fuel;
Figure 25 is a diagram showing Mole Flow Schematic of Biomass
Hydro-gasification for production of gaseous hydrogen fuel;
Figure 26 is a diagram showing Thermal Energy Management
Schematic of Biomass Hydro-gasification for production of gaseous hydrogen
fuel;
Figure 27 is a diagram showing Water/Steam Flow Schematic of
Biomass Hydro-gasification for production of gaseous hydrogen fuel;
Figure 28 is a diagram showing Molten Salt Flow Schematic of
Biomass Hydro-gasification for production of gaseous hydrogen fuel;
Figure 29 is a diagram showing Mass Flow Schematic of Biomass
Hydro-gasification for production of electricity;
Figure 30 is a diagram showing Mole Flow Schematic of Biomass
Hydro-gasification for production of electricity;
Figure 31 is a diagram showing Thermal energy Management
Schematic of Biomass Hydro-gasification for production of electricity;
Figure 32 is a diagram showing Water/Steam Flow Schematic of
Biomass Hydro-gasification for production of electricity;
Figure 33 is a diagram showing Molten Salt Flow Schematic of
Biomass Hydro-gasification for production of electricity;


Figure 34 is a mass flow schematic of biomass hydro-gasification
for Fischer-Tropsch paraffin fuel production using an adiabatic HGR and a 9:1
water feed;
Figure 35 is a molal flow schematic of biomass hydro-gasification
for Fischer-Tropsch paraffin fuel production using an adiabatic HGR and a 9:1
water feed;
Figure 36 is a thermal energy management schematic of biomass
hydro-gasification for Fischer-Tropsch paraffin fuel production using an
adiabatic HGR and a 9:1 water feed;
Figure 37 is a water/steam flow schematic of biomass hydro-
gasification for Fischer-Tropsch paraffin fuel production using an adiabatic
HGR and a 9:1 water feed;
Figure 38 is a molten salt flow schematic of biomass hydro-
gasification for Fischer-Tropsch paraffin fuel production using an adiabatic
HGR and a 9:1 water feed;
Figure 39 is a schematic diagram of a steam pyrolysis/hydro-
gasification micro-batch reactor coupled to a residual gas analyzer, in another
embodiment of the invention;
Figure 40 is a data record display of gas species produced in a
micro-batch reactor;
Figure 41 is a graph of rate constant measurements for methane
gas produced from pine wood material;
Figure 42 is a graph of rate constant measurements for carbon
dioxide gas produced from pine wood material;
Figure 43 is a graph showing the % carbon conversion for pine
wood material at various temperatures;


Figure 34 is a mass flow schematic of biomass hydro-gasification
for Fischer-Tropsch paraffin fuel production using an adiabatic HGR and a 9:1
water feed;
Figure 35 is a molal flow schematic of biomass hydro-gasification
for Fischer-Tropsch paraffin fuel production using an adiabatic HGR and a 9:1
water feed;
Figure 36 is a thermal energy management schematic of biomass
hydro-gasification for Fischer-Tropsch paraffin fuel production using an
adiabatic HGR and a 9:1 water feed;
Figure 37 is a water/steam flow schematic of biomass hydro-
gasification for Fischer-Tropsch paraffin fuel production using an adiabatic
HGR and a 9:1 water feed;
Figure 38 is a molten salt flow schematic of biomass hydro-
gasification for Fischer-Tropsch paraffin fuel production using an adiabatic
HGR and a 9:1 water feed;
Figure 39 is a schematic diagram of a steam pyrolysis/hydro-
gasification micro-batch reactor coupled to a residual gas analyzer, in another
embodiment of the invention;
Figure 40 is a data record display of gas species produced in a
micro-batch reactor;
Figure 41 is a graph of rate constant measurements for methane
gas produced from pine wood material;
Figure 42 is a graph of rate constant measurements for carbon
dioxide gas produced from pine wood material;
Figure 43 is a graph showing the % carbon conversion for pine
wood material at various temperatures;


Figure 44 is a graph of product gas composition at 770 °C for pine
wood material;
Figure 45 is a graph showing carbon conversion into energetic
gases for pine wood material at various temperatures;
Figure 46 is a graph of % carbon conversion of pine wood material
at various particle sizes;
Figure 47 is a graph of gas production from pine wood material at
various reactor pressures;
Figure 48 is data record display of gas species produced from
polyurethane foam material at 660 °C;
Figure 49 is data record display of gas species produced from
polyurethane foam material at 680 °C and a starting pressure of 12.4 bar;
Figure 50 is data record display of gas species produced from
polyurethane foam material at 680 °C and a starting pressure of 19.3 bar;
Figure 51 is data record display of gas species produced from
polyvinylchloride material at 720 °C;
Figure 52 is data record display of gas species produced from
polyvinylchloride material at 700 °C;
Figure 53 is data record display of gas species produced from
polymeric tire rubber material at 700 °C and a starting pressure of 45.5 bar;
Figure 54 is data record display of gas species produced from
polymeric tire rubber material at 700 °C and a starting pressure of 41.4 bar;
and
Figure 55 is a graph of methane production rates under different
pyrolysis conditions.


DETAILED DESCRIPTION OF THE INVENTION
In one embodiment of the invention, a steam generator for
pyrolysis, hydro-gasification reactor (HGR) and steam pyrolytic reformer
(SPR) (also called a steam pyrolytic reactor, steam reformer or steam reactor)
such as used in a Hynol process, may be utilized to produce the synthesis
gas (syngas) through steam pyrolysis of the feed stock, hydro-gasification and
steam reforming reactions. The reactions start in the HGR to convert carbon
in the carbonaceous matter into a methane rich producer gas and continue
through the SPR to produce synthesis gas with the correct hydrogen and
carbon monoxide stoichiometry for efficient operation of the Fischer-Tropsch
process. With the Fischer-Tropsch process as the final step in processing,
products such as synthetic gasoline, synthetic diesel fuel and recycled water
can be produced.
The feedstock requirement is highly flexible. Many feeds that
consist of different carbonaceous materials can be wet milled to form a water
slurry that can be fed at high pressure into a steam pyrolyzer, hydro-gasifier
and steam reformer reactors for synthesis gas production. The feed to water
mass ratio can even vary during the running of the process, with a knowledge
of the chemical content of the feed, to maintain the carbon-hydrogen
stiochiometry required for an optimized fuel synthesis process. Appropriate
carbonaceous materials include biomass, natural gas, oil, petroleum coke,
coal, petrochemical and refinery by-products and wastes, plastics, tires,
sewage sludge and other organic wastes. For example, wood is an example
of waste biomass material that is readily available in Riverside County,
California. This particular waste stream could be augmented with other
carbonaceous materials, such as green waste and biosolids from water
treatment that are available in Riverside County, and would otherwise go to
landfill.
When used to make a transportation fuel, such as diesel fuel, the
process is designed so that the feedstock makes the maximum amount of


Fischer-Tropsch paraffinic product required. The desired output consists of a
liquid hydrocarbon, such as cetane, C16H34, within the carbon number range,
12 to 20, suitable as a diesel fuel. Excess synthesis gas output from the SPR,
i.e., "leftover" chemical energy from the Fischer Tropsch synthetic fuel
producing process, can be used as an energetic fuel to run a gas turbine for
electricity production. The synthesis gas output after recycling enough
hydrogen to sustain the hydro-gasifier, may be used for this purpose also,
depending on the needs of the user. The following provides a method for
maximizing the economic potential from the present invention in the
conversion of carbonaceous materials to a usable transportation fuels and
inclusive of the possibility for direct electric power production through a gas
turbine combined cycle.
1) Find approximate data on available carbonaceous wastes, their
chemical composition and perform further analysis on the practical need for
the process.
2) Model the important reactions within the process consisting of
the steam generator for pyrolysis, hydro-gasifier, steam reformer, and the
Fischer-Tropsch (or other fuel synthesis) reactor on a continuous flow-through
basis. This may be done by optimizing the Fischer-Tropsch (or other fuel
synthesizer) feedstock for the optimum stoichiometric hydrogen to carbon
monoxide mole ratio for fuel to be synthesized.
3) Perform an economic analysis on the costs to obtain and
prepare the input material required, capital costs, operating and maintenance,
and product yield and costs.
Specific implementations are given below in conjunction with flow
charts provided in the Figures, demonstrating the conversion of waste wood,
as the candidate carbonaceous material, to a liquid diesel transportation fuel,
recycled water and an alternative power source, via a Fischer-Tropsch
process linked to a gas turbine combined cycle.


The thermo-chemical conversion of carbonaceous materials occurs
by two main processes: hydro-gasification and steam reformation, with steam
pyrolysis of the feedstock occurring within the steam generator to pre-treat
feedstock and activate the carbon contained therein. The hydro-gasifier
requires an input of the pyrolyzed carbonaceous waste, hydrogen, steam,
reacting in a vessel at high temperature and pressure, which in a specific
implementation is approximately 30 atmospheres and 1000 degrees Celsius.
Steam reforming of the methane rich effluent gas from the HGR also requires
an approximate pressure of 30 atmospheres and 1000 degrees Celsius.
More generally, each process can be conducted over a temperature range of
about 700 to 1200 degrees Celsius and a pressure of about 20 to 50
atmospheres. Lower temperatures and pressures can produce useful
reaction rates with the use of appropriate reaction catalysts or steam pyrolysis
processes. When combining steam pyrolysis and hydro-gasification in a
common reactor vessel, the inventors have found that adequate reaction
kinetics can be achieved at temperatures up to 750 degrees Celsius.
Referring to Figure 1, which is an overall flow diagram, the order of
general processes that carry out these main reaction processes is shown
(specific amounts for a particular embodiment are in the flow diagrams shown
in Figures 14 through 38). Piping is used to convey the materials through the
process. The feed 11 is chopped, milled or ground in a grinder 10 into small
particles, mixed with the recycled water 12 and placed in a receptacle or tank
14 as a liquid, suspension slurry 16 that is transportable as a compressed
fluid by a pump 18 to a steam generator 20 where the slurry 16 is
superheated and pyrolyzed, followed by either separation of the steam in a
steam separator 22 so that steam goes through piping 24 that is separate
from piping that delivers the pumped, dense slurry paste 26, or a direct steam
pyrolysis feed through piping 27.
The dense slurry paste feed 26, or the direct steam pyrolysis feed
27, enters the HGR 28. Hydrogen from an internal source (from the steam

reformer via a hydrogen separation filter described below) and a fraction of
the previously produced steam flow into the HGR 28 for the desired output.
The output gases consists largely of methane, hydrogen, carbon monoxide,
and super-heated steam. The gases produced by the HGR 28 leaves the
chamber and is pumped over to the SPR 30. The un-reacted residue (or ash)
from the HGR, is periodically removed from the bottom of the reactor vessel
using a double buffered lock-hopper arrangement, that is commonly used in
comparable high pressure gasification systems. The ash is expected to be
comprised of sand, SiO2, and alumina, AI2O3, with trace amounts of metals.
The input to the SPR 30 is delivered from either the steam separator 22 by
piping 32 through a heater 34 and further piping 36, or via the HGR 28 output
piping, to provide greater-than-theoretical steam to carbon ratio into the SPR
30, to mitigate coking in the reactor. The output is a higher amount of
hydrogen, and CO, with the appropriate stiochiometry for the desired
hydrocarbon fuel synthesis process described below.
The output of the SPR 30 is directed via piping 38 through heat
exchangers 40 and 42. Condensed water 44 is separated and removed from
the SPR output, via a heat exchanger and liquid water expander 47. The non-
condensable gaseous output of SPR 30 is then conveyed to a hydrogen
separation filter 46. A portion of the hydrogen from the SPR output, about
one-half in this embodiment, is carried from the filter 46, passed through the
heat exchanger 40 with a resultant rise in its temperature (in the embodiment
from 220 degrees centigrade to 970 degrees Centigrade) and delivered to the
HGR 28 as its hydrogen input. The hot effluent from the SPR output is cooled
by passing through heat exchangers 40 and 42, used to heat the recycled
hydrogen, and make steam respectively. The condensed water 44 leaving the
heat exchanger 47 is recycled back to make the water supply 12 for the slurry
feed. By such means, a self-sustaining process is obtained.
The fuel synthesis gas is then used for one of two options. Based
on the calorific value, the synthesis gas may go through a gas turbine


combined cycle for direct energy production or through a fuel synthesis
reactor (in this embodiment, a Fischer-Tropsch process to produce a clean
diesel fuel and recycled water). In accordance with a specific embodiment of
the invention, the synthesis gas is directed through an expansion turbine 48,
to recover mechanical energy by lowering the pressure of the gaseous feed
into the Fischer-Tropsch reactor 50. The mechanical power produced by the
liquid state turbine, the Brayton and Rankine cycle turbines can be used to
provide power for internal slurry, water feed pumps, air compressor, with the
surplus exported via electricity generation, see Tables 1 through 7.
Efficiency may be maximized by adjusting input and process
parameters. The biomass/ coal varying-mixture feed is synthesized into a
slurry by adding water whereby after steam separation the carbon to
hydrogen ratio will be appropriate for the process. A slurry feed needs
enough water to run the hydro-gasifier, the steam reformer, and to keep the
feed in a viable slurry after steam separation. Prior art attempts at biomass
conversion using solid dry feed had many mechanical problems of feeding a
solid into the high pressure, and high temperature HGR reaction chamber.
This method of slurry feed has already been demonstrated and studied,
according to the results for the "Hydrothermal Treatment of Municipal Solid
Waste to Form High Solids Slurries in a Pilot Scale System", by C. B.
Thorsness et al., UCRL-ID 119685, published by Lawrence Livermore Nation
Laboratory, Livermore, CA in 1995. In addition, there is related art published
on the making and operating of coal water slurry feeds. For example, see Z.
Aktas et al., Fuel Processing Technology 62 2000 1-15. The principle
reactions of the two main processes, hydro-gasification and steam reforming,
are shown here. The HGR independent reactions can be expressed as:


Reactions 2 and 3 are endothermic. Reaction 1 is sufficiently
exothermic to provide the heat of reaction for reactions 2 and 3. Some
preheating of the HGR will be needed to bring the reactor up to its operating
temperature. Thus, the HGR is intended to be self-sustaining once the
reactions have started and achieve steady state.
The main purpose of the HGR process is to maximize the carbon
conversion from the feed stock into the energetic gases CH4 and CO. After
this process, hydrogen is produced by reacting superheated steam with CH4
and CO within the SPR. In the SPR, half the hydrogen is obtained from the
superheated steam and the remainder from the CH4. The principle reactions
in the SPR are considered to be:

The steam reforming reactions (4 and 5) are often run with steam
concentrations higher than required for the stiochiometry shown above. This
is done to avoid coke formation and to improve conversion efficiency. The
required steam concentration is usually specified in the form of the
steam-to-carbon mole ratio (S:C), the ratio of water steam molecules per
carbon atom in the HGR feed. The preferred (S:C) ratio for the SPR
operation is greater than 3. This steam rich condition favors the water-gas
shift reaction. This reaction is only slightly exothermic (∆H°= -41 kJ/mole
CO); however, it produces additional hydrogen gas and converts carbon
monoxide into carbon dioxide. Unfortunately, an additional unwanted
secondary reaction can occur, the methanation reaction, which consumes
hydrogen:


The resulting effluent after the two main reactors is a synthesis of
gases rich in hydrogen, carbon monoxide, and steam. Approximately half the
hydrogen produced in the SPR is recycled back to the HGR. Consequently,
no outside source of hydrogen is needed to maintain steady state operation.
The HGR and SPR processes, therefore, may be considered to be chemically
self-sustaining. The remaining synthesis gas is then available for the
production of fuels and process heat.
The present invention using the Fischer-Tropsch process can
produce a zero-sulfur, ultrahigh cetane value diesel-like fuel and valuable
paraffin wax products. The absence of sulfur enables low pollutant and
particle emitting diesel fuels to be realized.
The present invention also provides a source of by-products. One
useful by-product is purified water, which can be re-cycled to create the slurry
feed into the process. In a report by Rentech titled "Fischer-Tropsch
technology" dated 1998 (see Rentech web publications at rentechinc.com),
Rentech states that the Fischer-Tropsch process with ah iron catalyst makes
about 7/10ths of a barrel of water per barrel of Fischer-Tropsch products. A
cobalt catalyzed Fischer-Tropsch process makes about 1.1 to 1.3 barrels of
water for each barrel of Fischer-Tropsch products, a greater amount than iron.
Part of the water may be recycled to make steam in the steam reformer unit
and for cooling in both the synthesis gas and Fischer-Tropsch step of the
overall process.
The Fischer-Tropsch reactions also produce tail gas that contains
hydrogen, CO, CO2, and some light hydrocarbon gases. Hydrogen can be
stripped out of the tail gas and recycled either to the HGR or the Fischer-
Tropsch reactor. Any small amounts of other gases such as CO and CO2
may be flared off.
Two main products of Fischer-Tropsch may be characterized as
synthetic oil and petroleum wax. According to Rentech, in the above report


for their particular implementation of the Fischer-Tropsch process, the mix of
solid wax to liquid ratio is about 50/50. Fischer-Tropsch products are totally
free of sulfur, nitrogen, nickel, vanadium, asphaltenes, and aromatics that are
typically found in crude oil. The products are almost exclusively paraffins and
olefins with very few, or no, complex cyclic hydrocarbons or oxygenates that
would otherwise require further separation and/or processing in order to be
usable end-products. The absence of sulfur, nitrogen, and aromatics
substantially reduces harmful emissions.
California's Air Resources Board (CARB) specifications for diesel
fuel require a minimum cetane value of 48 and reduced sulfur content. The
above Rentech study with Shell diesel fuel produced from a Fischer-Tropsch
process has a cetane value of 76. The CARB standard for sulfur in diesel fuel
placed in the vehicle tank is 500 ppm by weight, and Shell's Fischer-Tropsch
process diesel fuel has no detectable amount in the ppm range. The CARB
standard for aromatic content is no more than 10% by volume (20% for small
refineries). The Shell Fischer-Tropsch process diesel fuel had no detectable
aromatics.
Rentech further affirmed through studies that the diesel fuel may
need no further processing because of the purity and olefin products that may
even be advantageous over crude oil diesel. The Fischer-Tropsch diesel
process is clean and the product is cleaner, has a higher cetane value, and
most likely does not need further processing, when compared to a crude oil
diesel.
A gas turbine combined cycle for electric power production is an
option. If the Fischer-Tropsch product is unexpectedly too costly, the use of
the synthesis gas heating value can be a viable option, based on an overall
efficiency of 65% of the synthesis gas energy converting to electric energy.
This number is reasonable since the synthesis gas starts at a high
temperature as opposed to taking natural gas in from a pipeline.


Process modeling can be used to reasonably produce a synthesis
gas maximized for a yield high in CO and stoichiometric hydrogen. First, the
unit operation reactions of the hydro-gasifier, steam reformer, and
Fischer-Tropsch reactors are modeled. This may be accomplished by using
Stanjan, a DOS-based computer program that uses equilibrium modeling. By
varying the parameters of temperature, pressure, original feedstock and gas
flows, a parameterization study was carried out based on costs and output
benefit. The hydro-gasifier variables were modified for the maximum practical
carbon conversion efficiency. The steam reformer variables were modified for
maximum practical CO output, enough hydrogen for recycling output, and
minimum CO2 production. The study looked at the various parameters
whereby two different values varied for one constant, resulting in 3-D
parameterization studies. The following discusses the results from the
computer modeling of the main reactions using Stanjan programming.
Referring to Figure 2, the effect of varying the water or steam and
hydrogen ratios on the conversion efficiency of carbon in feedstock in the
HGR is shown at 800°C and 30 atm. As the hydrogen and water input to the
HGR increases, the conversion efficiency of carbon in feedstock increases
until it reaches 100%. The condition that falls in the area of 100% conversion
efficiency achieves one of the modeling objectives, and these conditions were
used. In order to avoid the cost of recycling of H2, the minimum amount of H2
recycled to the HGR must be chosen. Figure 3 shows the effect of H2 and
H2O on CH4 in the HGR at 800°C and 30 atm. Figure 4 shows the effect of H2
and H2O on CO2 in the HGR at 800°C and 30 atm. At a high amount of H2
and low amount of H2O input, the amount of CO2 is low. Although the
objective is to minimize the amount of CO2 in the synthesis gas, it is not
necessary to minimize CO2 in the HGR because CO2 is gauged in the SPR
reactions through the water-gas-shift reaction to obtain a proper ratio of H2
and CO for a maximum Fischer-Tropsch diesel fraction. Figure 5 shows the
effect of H2 and H2O on CO in the HGR at 800°C and 30 atm.


Figures 6, 7, 8 and 9 show the effects of varying temperature and
pressure on the chemical composition of the effluent gases from the HGR at
feed of 2.76 mol H2 and 0.066 mol H2O per mole C in the feed stock. At these
conditions of H2 and H2O input to the HGR, the carbon conversion efficiency
is estimated to close to 100% in a temperature range of 800 to 1000°C and a
pressure range of 30 atm. to 50 atm, for equilibrium chemistry.
Figure 10 shows the ratio of H2 and CO available for feed into the
Fischer-Tropsch fuel synthesis reactor, against the steam content added to
the SPR at 800°C and 30atm. This ratio increases with the increasing amount
of steam added to the SPR and reaches 2.1 at about 3.94 mol steam (or
water) added per mol C in feedstock. With this amount of steam added, the
system will achieve chemical and thermal self-sustainability and provide a
proper ratio of H2 and CO for Fischer-Tropsch synthesis of cetane. Figure 11
shows the effect of H2O added to the SPR at 800°C and 30atm. Figures 12
and 13 show the effect of temperature and pressure on the H2 and CO ratio
and the conversion of CH4 in the SPR. At higher temperature and lower
pressure, this ratio is higher. In a similar trend with the H2 and CO ratio, the
conversion of CH4 increases with increasing temperature and with decreasing
pressure. It is thus high temperature and low pressure favored in the SPR.
The products of Fischer-Tropsch paraffinic liquid fuels are in a wide
range of carbon number. According to the above Rentech report, about half
of the products are diesel fuel. Also about half of the products come in the
form of wax, with minor amounts of gases such as un-reacted reactants and
hydrocarbon gases (methane, ethane, propane and so forth). To exemplify
the present invention, cetane, which is in middle position of diesel range (C11
to C20), was chosen as diesel fuel.
The results of thermo-chemical and thermodynamic modeling of the
hydro-gasified conversion of waste wood (biomass), as a prototypical
carbonaceous feed material, were used to examine the details and illustrate
the features of this invention. These simulations of the novel sequence of

process reactors were undertaken to discover the thermo-chemical conditions
needed to achieve the production of synthetic fuels. For example, in the
production of synthetic diesel fuel, the objectives were to attain self-sustained
operation of the first stage hydro-gasifier. In a particular embodiment, this is
accomplished at an equilibrium temperature of 1000°C (738°C when
adiabatic) and 30 atmospheres pressure with a total hydrogen to carbon feed
mole ratio of at least 3.48:1 (1.67:1 when adiabatic), and water to carbon feed
ratio of at least 0.07:1 (0.43 when adiabatic), a water steam to carbon feed
mole ratio of at least 3.91:1 (1.67:1 when adiabatic) into the second stage
steam reforming reactor also operating at an equilibrium temperature of
1000°C (900°C when adiabatic) and 30 atmospheres pressure, to obtain
conditions for simultaneous optimal quantities of product hydrogen for self-
sustained operation of the first stage hydro-gasification reactor and an
adequate hydrogen to carbon mole ratio of at least 2.1:1 in the residual
synthesis gas stream to feed the third stage Fischer-Tropsch reactor,
operating at 200°C and 10 atmospheres pressure, and adiabatic self-
sustained operation of a special HGR and SPR combination reactor, followed
by a conventionally operated SPR and Fischer-Tropsch reactors, with full
thermal and chemical potential energy management. The inventors have
found that higher temperature Fischer-Tropsch reactors can provide higher
quality exothermic heat up to 350°C, with appropriate change in catalyst.
Tables 1 through 5 show the overall energy transfer rates into and
out from each heat exchanger and power conversion component for each
operating mode of the conversion process. The mass flow, molal flow, thermal
energy management, water/steam and molten salt schematic diagrams for
each of the five operating modes of the conversion process are also shown as
Figs14-18, 19-23, 24-28, 29-33 and 34-38 respectively. Tables 6 and 7
summarize the results of the performance studies and process configuration
parameters for each of the five operating modes of the conversion process.


The inventors have found that adequate kinetic performance of the
processes described can be achieved at temperatures of about 750°C. At
lower operating temperatures, about 800 °C or lower, a lower temperature
heat transfer fluid such as a molten salt system or a water-steam system
could be used to transfer heat. Thus, water-steam heat transfer loops can
replace the molten salt loops for transferring heat at lower operating
temperatures.
The carbonaceous material feed process initially described above
uses a water slurry suspension feed technology, originally developed by
Texaco for use in its partial-oxidation gasifiers, that can accept a wide variety
of carbonaceous materials, and can be metered by controlled pumping into
the first stage hydrogen gasification reactor (HGR) to produce a methane rich
gas with high conversion efficiency (measured to have at least 85% carbon
feed chemical utilization efficiency). Enough heat is available to be able to
generate super-heated steam from the biomass-water slurry feed to supply
and operate the second stage steam-methane reformer. The reformer product
gas is fed into a hydrogen membrane filter that allows almost pure hydrogen
to pass back into the first stage reactor to sustain the hydro-gasification of the
biomass. The remaining second stage product gas, not passing through the
hydrogen filter, is cooled to condense and re-cycle any water vapor present
back into the slurry carbonaceous feed system. The unfiltered gas is fed into
the fuel synthesis reactors, which comprise a Fischer-Tropsch paraffin hydro-
carbon synthesis reactor, which operates at 200°C and 10 atmospheres
pressure. Process modeling reveals that the hydrogen/carbon molecular feed
ratio must be at least 2.1:1 to optimize production of chemically pure and
clean-burning [sulfur-free] diesel-like liquid fuels and high value chemically
pure paraffin-like waxes, without additional fuel or energy. (Figs. 14-18 and
Tables 1, 6 and 7 or Figs. 34-38 and Tables 5, 6 and 7 for adiabatic first stage
reactor operation), or a dimethyl ether synthesis reactor, which operates at
200°C and 70 atmospheres pressure. This reactor produces approximately
92.4% DME and 7,1% methanol. The methanol is combusted to co-generate


about 30 MW of electricity and 20MW of process heat for exchange with the
molten salt and water/steam heat transfer loops (see Figs. 19-23 and Tables
2, 6 and 7), hydrogen gaseous fuel synthesis (see Figs. 24-28 and Tables 3, 6
and 7), and all electric power production without fuel synthesis (see Figs. 29-
33 and Table 4, 6 and 7).
Net export of electric power is possible in all five modes of
operation of the simulated biomass hydro-gasification process plant. The
results of these simulations are summarized in Table 6 and 7. The overall
energy utilization goes from 50.7% (71.2% when adiabatic) for Fischer-
Tropsch synthesis to 67.2% for hydrogen production. Optimized electric
power production utilizes about 38.2% of the chemical potential energy in the
biomass feed stock for clean-burning power conversion. In general the
process modes could be switched using an appropriate proportional valve to
distribute the synthesis gas production after separation of enough pure
hydrogen gas for the first stage hydro-gasification reactor.
The results of the overall modeling shown in Figure 1 are
summarized as follows.
1. Optimum conditions of the HGR: Operating at 1000°C and
30atm; 2.76 mol H2 per mol C in feedstock to maintain self-sustainability;
0.066 mol H2O per mol C in feedstock.
2. Optimum conditions of the SPR: Operating at 1000°C and
30atm; 4.022 mol H2O per mol C in feedstock.
3. Fischer-Tropsch products: 0.199 ton wax per ton of feedstock;
68.3 gallons of cetane (C16H34) diesel per ton of feedstock.
In another embodiment of the invention, a process is provided that
combines steam pyrolysis and hydro-gasification into a single step for the
production of energetic gases from carbonaceous material. The process
comprises heating carbonaceous material simultaneously in the presence of


both hydrogen and steam. At sufficient temperatures and pressures, steam
pyrolysis can enhance the hydro-gasification of carbonaceous materials.
The combination of steam pyrolysis and hydro-gasification can
enhance the rates at which hydrocarbon gases are produced from natural and
synthetic carbonaceous substances such as plant material, coal and synthetic
polymers, and from carbonaceous materials such as biomass and municipal
waste containing such natural and synthetic substances.
By combining steam pyrolysis and hydro-gasification into a single
step, a carbonaceous material can be effectively converted into energetic
gases without first subjecting the material to a separate steam pyrolysis step.
More particularly, in accordance with the present invention, non-pyrolyzed
carbonaceous material can bypass the steam generator and go directly into
the hydro-gasification reactor, where the non-pyrolyzed carbonaceous
material can undergo the combined process of steam pyrolysis and hydro-
gasification. The carbonaceous material can be prepared as a slurry, which is
fed into the hydro-gasification reactor through piping that connects a source of
the slurry to the reactor. Steam can be fed into the reactor through piping
from the steam generator, and hydrogen can be fed into the reactor through
piping from the steam pyrolytic reformer.
The following Examples illustrate the process of combining steam
pyrolysis and hydro-gasification in the production of energetic gases from
wood (Examples 1 -7), synthetic polymers (Examples 8-10), and coal
(Example 11).
Example 1
This example provides a way to carry out steam pyrolysis and
hydro-gasification in a micro-batch reactor using real time analysis of gases.
Pine wood bedding chip material was used as a representative
carbonaceous material. Referring to Figure 39, the pine wood material, water
and a gas were added to a reactor vessel 62 and quickly brought to a desired


temperature by immersing the vessel in a molten salt bath 64. The vessel
was directly coupled to a sample injector 66 and a residual gas analyzer 68
for real-time analysis of the various gas species produced by pyrolysis and
hydro-gasification. The partial pressures of the gas species were determined
over the course the reaction.
Figure 40 provides a typical data record display of the experimental
results. Partial pressures values over time are shown for hydrogen 70,
methane 72, carbon monoxide 74, and carbon dioxide 76, as well as other
gas species.
In a typical set of experiments, the process combining steam
pyrolysis and hydro-gasification was compared with three other types of
pyrolytic processes - dry pyrolysis with helium gas, dry pyrolysis with
hydrogen gas, and steam pyrolysis with helium gas.
The dry pyrolysis process with helium gas was carried out by
adding a pine wood sample and helium to the reactor vessel, then heating.
Although no water was added to the reactor vessel, some water may have
been present in the pine wood sample due to incomplete drying of the pine
wood material. Because helium is an inert gas, this process can be
considered to generate products only as a result of thermolysis.
The dry pyrolysis process with hydrogen gas was carried out by
adding a pine wood sample and hydrogen to the reactor vessel, then heating.
No water was added. Since hydrogen gas is not inert, the dry pyrolysis of the
pine wood sample in the presence of hydrogen will induce reduction reactions
with elements in the biomass molecules as well as any pyrolytic action
dissociating the biomass molecules by thermolysis.
The steam pyrolysis process with helium gas is considered
representative of the steam pyrolysis process by itself. The process was
carried out by adding pine wood material, water and helium to the reactor
vessel, then heating.
21

Table 8 provides an analysis of the pine wood material used in the
example compared with pine wood material used by others in previous
studies. Values for the elemental (or "ultimate") analysis indicate that the pine
wood used in the example is comparable to that studied by others.
Example 2
This example provides rate constant measurements for the
production of methane gas and carbon monoxide from pine wood material
subjected to the four pyrolytic processes.
Each pyrolytic process was carried out as described in Example 1.
Process temperatures were about 580 - 600 °C ("600 °C"), 670 - 690 °C
("670 °C"), and 770 - 790 °C ("770 °C"). The nominal particle size of the pine
wood samples was less than about 425 microns (0.425 mm diameter).
Figure 41 provides a bar graph showing rate constants in moles per
minute for the production of methane gas at different temperatures. At each
temperature, the rate constant for steam pyrolysis with helium was greater
than the rate constant for either dry pyrolysis process. For example, the rate
constant 78 for steam pyrolysis at 670 °C was greater than the rate constant
80 for dry pyrolysis with helium and the rate constant 82 for dry pyrolysis with
hydrogen. Further, at both 670 °C and 770 °C, the rate constants for the
combined process of steam pyrolysis and hydro-gasification were greater than
the rate constants for steam pyrolysis alone. For example, at 770 °C, the rate
constant 84 for steam pyrolysis and hydro-gasification was about twice as
great as the rate constant 86 for steam pyrolysis.
Similar results are shown in Figure 42, which provides a bar graph
showing rate constants for the production of carbon monoxide at various
temperatures. Again, at each temperature, the rate constant was greater for
steam pyrolysis than for either dry pyrolysis process. Also, at 770 °C, the rate
constant for steam pyrolysis and hydro-gasification was greater than the rate
constant for steam pyrolysis alone.


These results indicate that steam pyrolysis alone, or combined with
hydro-gasification, can provide increased rates of production of methane gas
and carbon monoxide from carbonaceous material, and that rates of
production for the process of steam pyrolysis and hydro-gasification can
exceed rates of production for the process of steam pyrolysis alone.
Example 3
This example provides measurements of the total conversion of
carbon to carbon containing gases for pine wood material subjected to the
four pyrolytic processes.
Each pyrolytic process was carried out as described in Example 2.
Figure 43 is a bar graph showing the % conversion of carbon to
carbon containing gases at different temperatures. At each temperature, the
% conversion was greater for steam pyrolysis than for either dry pyrolysis
process. In addition, at 670 °C and 770 °C, the % conversion for steam
pyrolysis and hydro-gasification was greater than the % conversion for steam
pyrolysis alone.
These data indicate that steam pyrolysis alone, or combined with
hydro-gasification, can enhance the total conversion of carbon to carbon
containing gases, and that conversion by steam pyrolysis and hydro-
gasification can be greater than by steam pyrolysis alone. Further, the
advantages of steam pyrolysis and hydro-gasification can improve with
increasing temperature.
Example 4
This example provides an analysis of the gas species produced
from pine wood material subjected to one of the four pyrolytic processes.
Each pyrolytic reaction was carried out as in Example 1 at a reactor
temperature of about 770 °C.


Figure 44 is a bar graph showing the product gas composition for
each pyrolytic process. The results indicate that steam pyrolysis can shift the
product gases away from the oxides of carbon and to the hydrocarbon gases,
with methane in the lead. For example, dry pyrolysis with helium produced a
gas composition 88 for carbon monoxide of about 64% and a gas composition
90 for carbon dioxide of about 18%, for a total carbon oxides composition of
about 82%. The gas composition 92 for methane was about 14% for dry
pyrolysis with helium. With steam pyrolysis, the gas composition 94 for
carbon monoxide was about 45% and the gas composition 96 for carbon
dioxide about 26%, for a total carbon oxides composition of about 71%, while
the gas composition 98 for methane was raised to about 22%.
In addition, the methane composition 100 for steam pyrolysis and
hydro-gasification was greater than the methane composition 98 for steam
pyrolysis alone. The results indicate that the process of steam pyrolysis and
hydro-gasification can provide more hydrocarbon gases than steam pyrolysis
alone.
Example 5
This example provides measurements of carbon conversion into
energetic gases for pine wood subjected to the four pyrolytic processes.
Each pyrolytic reaction was carried out as described in Example 2.
Figure 45 is a bar graph showing the % carbon conversion into
energetic gases at different temperatures. The energetic gases included all
gases produced except carbon dioxide and water vapor. The % carbon
conversion was greater for steam pyrolysis than for either dry pyrolysis
process. Also, at 670 °C and 770 °C, the % carbon conversion for steam
pyrolysis and hydro-gasification was greater than the % carbon conversion for
steam pyrolysis alone.
These results indicate that steam pyrolysis alone, or steam
pyrolysis combined with hydro-gasification, can enhance the total conversion


of carbon into energetic gases, and also indicate that conversion by steam
pyrolysis and hydro-gasification can be greater than by steam pyrolysis alone.
In addition, the advantages of steam pyrolysis and hydro-gasification over
steam pyrolysis alone can improve with increasing temperature.
Example 6
This example provides % carbon conversion at various particle
sizes in a micro-batch reactor.
Dry pyrolysis with hydrogen, and steam pyrolysis combined with
hydro-gasification, were carried out as in Example 1. The temperature range
was about 660-680 °C. Three nominal particle size ranges were evaluated:
less than about 425 microns (0.425 mm diameter); about 425 -500 microns
(O.425-.500 mm diameter); and about 500-1000 microns (0.500-1 mm
diameter).
Figure 46 is a bar graph showing % carbon conversion at different
particle size ranges. The % carbon conversion 102 for steam pyrolysis and
hydro-gasification in the 425-500 micron particle size range was similar to the
% carbon conversion 104 for steam pyrolysis and hydro-gasification in the
500-1000 microns particle size range. In this experiment, particle sizes less
than 1000 microns did not appear to enhance carbon conversion in the micro-
batch reactor under the experimental conditions employed.
Example 7
This example shows gas production from pine wood material at
various micro-batch reactor pressures.
Steam pyrolysis combined with hydro-gasification was performed as
in Example 1 at a temperature range of about 770-790 °C, with a nominal pine
wood particle size of less than about 425 microns, and a pressure of about 10
bar (132 psig) or 39 bar (560 pi).

Figure 47 is a graph showing the product gas composition for each
of the most abundant gas species produced at the two different pressures.
Similar to the results of Example 4 and Figure 6, the total gas composition of
carbon monoxide and carbon dioxide at high pressure was less than the total
gas composition of the carbon oxides at low pressure. Also, the methane
composition was greater at higher pressure. These results indicate that an
increase in pressure can push the reduction of carbon in the direction of
hydrocarbon gases at the expense of carbon oxides. This can provide a
process which promotes the production of methane gas while simultaneously
reducing the production of carbon oxides.
Example 8
This example provides the results of experiments in which
poiyurethane foam material was subjected to steam pyrolysis and hydro-
gasification at different temperatures and pressures.
The combination of steam pyrolysis and hydro-gasification was
carried out as in Example 1, with ground poiyurethane foam material of about
0.5 to 1 mm in diameter as the carbonaceous material. Figure 48 provides
the results for a reaction carried out at a temperature of about 660 °C, a
starting pressure of about 11.0 bar, and a steam to sample mass ratio of
about 0.5:1. Partial pressure values over time are shown for hydrogen 106,
methane 108, carbon monoxide 110, and carbon dioxide 112.
Figure 49 provides the results for a reaction carried out at a
temperature of about 680 °C, a starting pressure of about 12.4 bar, and a
steam to sample mass ratio of about 1:1. Partial pressure values over time
are shown for hydrogen 114, methane 116, carbon monoxide 118, and carbon
dioxide 120.
Figure 50 provides the results for a reaction carried out at a
temperature of about 680 °C, a starting pressure of about 19.3 bar, and a
steam to sample mass ratio of about 2:1. Partial pressure values over time


are shown for methane 122, C3H8 124, carbon monoxide 126, and carbon
dioxide 128.
EXAMPLE 9
This example provides the results of experiments in which
polyvinylchloride ("PVC") material was subjected to steam pyrolysis and
hydro-gasification.
Steam pyrolysis was carried out as in Example 1, with ground PVC
material of about 0.5 to 1 mm in diameter as the carbonaceous material and
argon gas substituting for helium as the inert gas. Figure 51 provides the
results for a steam pyrolysis reaction carried out at a temperature of about
720 °C, a starting pressure of about 41.4 bar, and a steam to sample mass
ratio of about 1:1. Partial pressure values over time are shown for hydrogen
130, methane 132, carbon monoxide 134, carbon dioxide 136, and argon gas
138.
The combination of steam pyrolysis and hydro-gasification was
carried out as in Example 1, at a temperature of about 700 °C, a starting
pressure of about 31.0 bar, and a steam to sample mass ratio of about 1:1.
Figure 52 provides the results of the reaction. Partial pressure values over
time are shown for hydrogen 140 (values shown as H2/10), methane 142,
C2H6 144, carbon monoxide 146, and carbon dioxide 148.
EXAMPLE 10
This example provides the results of experiments in which
polymeric tire rubber material was subjected to steam pyrolysis and hydro-
gasification.
Steam pyrolysis in helium gas was carried out as in Example 1, with
ground polymeric tire rubber material of about 0.5 to 1 mm in diameter as the
carbonaceous material. Figure 53 provides the results for a reaction carried
out at a temperature of about 700 °C, a starting pressure of about 45.5 bar,
and a steam to rubber mass ratio of about 1:1. Partial pressure values over


time are shown for hydrogen 150, methane 152, C2H6 154, and carbon
monoxide 156.
Figure 54 provides the results for a reaction combining steam
pyrolysis and hydro-gasification, carried out at a temperature of about 700 °C,
a starting pressure of about 41.4 bar, and a steam to sample mass ratio of
about 1:1. Partial pressure values over time are shown for hydrogen 158,
methane 160, and C2H6162.
Quantitative data obtained from the experiments presented in
Examples 8-10 are summarized in Table 9 for polyurethane foam ("PUF"),
polyvinylchloride, and polymeric tire rubber ("TR"). The table lists: a) the
process used - hydro-gasification ("HGR") and/or steam pyrolysis ("SPY");
b) the steam to sample mass ratio; c) the batch-reactor temperature
maintained by the molten salt bath; d) the maximum internal batch-reactor
pressure attained during the experiment; e) the time ("t m rate") from the start
of the experiment for the major gaseous product, methane, to achieve its
maximum production rate; f) the measured maximum rate of methane
production ("d[CH4]/dt") in mole percent per second; and g) the ratio of the
value defined above to the standard value for hydro-gasification without steam
pyrolysis.
The results for the polyurethane foam material show that the use of
steam pyrolysis can enhance the kinetic rate for the production of methane.
In these experiments, the maximum enhancement measured, for a steam to
sample mass ratio of 2, is a factor of 5.9 faster than the rate measured for a
steam to sample mass ratio of 0.5. Thus, increasing the quantity of steam
used in the steam pyrolysis process can enhance the hydro-gasification rate
for the production of methane.
The results for the PVC material are listed next in Table 9. The
measured rate of production of methane by steam pyrolysis and hydro-


gasification was increased by a factor of 3 above that for steam pyrolysis
alone.
Finally, the results of testing the polymeric tire rubber material are
listed. The measured rate of production of methane by steam pyrolysis and
hydro-gasification was increased by a factor of 1.5 above that for steam
pyrolysis alone.
The results summarized in Table 9 indicate that increased methane
production rates can be achieved in a hydrogasifier reactor when co-
processing plastic and polymeric samples with steam pyrolysis.
EXAMPLE 11
In this example, coal was subjected to steam pyrolysis and hydro-
gasification.
Steam pyrolysis and hydro-gasification were carried out as in
Example 1, with coal as the carbonaceous material. The coal composition
was about 74.9% wt carbon, 4.9% wt hydrogen, 1.2% wt nitrogen, 0.7% wt
sulfur and 11.9% wt minerals. Proximate analysis of the coal showed about
24.0% wt moisture, 10.0% wt ash, 35.2% wt vol. mat., 52.4% wt Fix. [C], and
mesh 60. The nominal start conditions for all experiments were sample mass
of about 100 mg, salt bath set temperature of about 700 °C, and gasification
agent fill pressure of about 6.0 bar at about 22 °C.
Table 10 provides the results for the processes of dry pyrolysis with
hydrogen gas ("Dry HGR"), dry pyrolysis with helium gas ("Dry pyro."), steam
pyrolysis with helium gas ("SPY"), and combined steam pyrolysis and hydro-
gasification ("HGR+S.PY"). The table lists: a) the gas used; b) the water to
coal sample mass ratio ("[H20]/[C]"); c) the measured methane production
rate ("d[CH4]/dt"), normalized for any changes in the absolute pressure in the
reactor; d) relative methane production rate ratio ("dry He [CH4]/dt"),
normalized to the methane production rate of dry pyrolysis with helium gas;


and e) relative methane production rate ratio ("dry H2 [CH4]/dt"), normalized
to the methane production rate of dry pyrolysis with hydrogen gas.
The results show that combining steam pyrolysis and hydro-gasification can
enhance the methane production from the volatile matter in the coal. In these
experiments, the methane production rate of steam pyrolysis in the presence
of helium gas was greater by a factor of over 42 times the rate without water
present. Similarly, the methane production rate of dry pyrolysis with hydrogen
gas was enhanced by about 40% over the rate of dry pyrolysis using an inert
gas, helium. However, there was a significant increase in the methane
production rate when hydro-gasification and steam pyrolysis were combined.
For example, the methane production rate was increased by close to a factor
of 10, when the water to coal mass ratio was about 1.5, and by a factor well
over 100 times the dry hydropyrolysis rate when the water to coal mass ratio
was about of 3.0.
These same results are shown graphically in the form of a bar chart
in Figure 55, where, for example, the water to coal mass ratio 164 for one bar
(read from the left axis) is positioned over the methane production rate 166 of
the same bar (read from the right axis).
These results indicate that combining steam pyrolysis with hydro-
gasification of coal can enhance methane production rates.
Although the present invention and its advantages have been
described in detail, it should be understood that various changes,
substitutions and alterations can be made herein without departing from the
spirit and scope of the invention as defined by the appended claims.
Moreover, the scope of the present application is not intended to be limited to
the particular embodiments of the process and apparatus described in the
specification. As one of ordinary skill in the art will readily appreciate from the
disclosure of the present invention, processes and apparatuses, presently
existing or later to be developed that perform substantially the same function
or achieve substantially the same result as the corresponding embodiments


described herein may be utilized according to the present invention.
Accordingly, the appended claims are intended to include within their scope
such processes and apparatuses.





















We Claim:
1. A process for converting carbonaceous material to energetic gases, the process
comprising:
a) forming a liquid suspension slurry of particles of carbonaceous material in
water; and
b) feeding hydrogen and the suspension slurry into a hydrogasification reactor
without a reaction catalyst at a temperature and pressure sufficient to generate methane and
carbon monoxide rich producer gases wherein the ratio of water to dry carbonaceous material
in the hydrogasification reactor is at least 2:1.
2. The process as claimed in claim 1 wherein the temperature in step b) is 580°C to
790°C.
3. The process as claimed in claim 1 wherein the pressure in step b) is 132 psi to 560
psi.
4. The process as claimed in claim 1 wherein the carbonaceous material has a nominal
particle size of 1 mm in diameter.
5. The process as claimed in claim 1 wherein the carbonaceous material comprises
municipal waste, biomass, wood, coal, or a natural or synthetic polymer.
6. The process as claimed in claim 5 wherein the carbonaceous material comprises
biomass.
7. The process as claimed in claim 5 wherein the carbonaceous material comprises
municipal waste which comprises wood or a natural or synthetic polymer.
8. A process for converting carbonaceous material to energetic gases, the process
comprising:
a) forming a liquid suspension slurry of particles of carbonaceous material in
water; and

b) feeding hydrogen and the suspension slurry into a hydrogasification reactor
without a reaction catalyst at a temperature and pressure sufficient to generate methane and
carbon monoxide rich producer gases, wherein the ratio of water to dry carbonaceous
material in the hydrogasification reactor is at least 2:1,
wherein the carbonaceous material comprises wood or a natural or synthetic polymer.
9. The process as claimed in claim 1 for producing a synthesis gas, the process
comprising:
a) forming a liquid suspension slurry of particles of carbonaceous material in water;
b) feeding hydrogen and the suspension slurry into a hydrogasification reactor
without a reaction catalyst at a temperature and pressure sufficient to generate methane and
carbon monoxide rich producer gases, wherein the ratio of water to dry carbonaceous material in
the hydrogasification reactor is at least 2:1, and
c) subjecting the methane and carbon monoxide rich producer gases to steam
reforming reactions under conditions whereby synthesis gas comprising hydrogen and carbon
monoxide is generated.

10. The process as claimed in claim 9 wherein the carbonaceous material is non-
pyrolyzed carbonaceous material.
11. The process as claimed in claim 9 wherein the carbonaceous material comprises
municipal waste, biomass, wood, coal, or a natural or synthetic polymer.
12. The process as claimed in claim 11 wherein the carbonaceous material comprises
biomass.
13. The process as claimed in claim 11 wherein the carbonaceous material comprises
municipal waste which comprises wood or a natural or synthetic polymer.
14. The process as claimed in claim 1 for producing a synthesis gas, the process
comprising

a) forming a liquid suspension slurry of particles of carbonaceous material in water;
b) feeding hydrogen and the suspension slurry into a hydrogasification reactor
without a reaction catalyst at a temperature and pressure sufficient to generate methane and

carbon monoxide rich producer gases, wherein the carbonaceous material comprises wood or a
natural or synthetic polymer, wherein the ratio of water to dry carbonaceous material in the
hydrogasification reactor is at least 2:1; and
c) subjecting the methane and carbon monoxide rich producer gases to steam
reforming reactions under conditions whereby synthesis gas comprising hydrogen and carbon
monoxide is generated.
15. The process as claimed in claim 1 for producing a liquid fuel, the process comprising:
a) forming a liquid suspension slurry of particles of carbonaceous material in water;
b) feeding hydrogen and the suspension slurry into a hydrogasification reactor
without a reaction catalyst at a temperature and pressure sufficient to generate methane and
carbon monoxide rich producer gases, wherein the ratio of water to dry carbonaceous material in
the hydrogasification reactor is at least 2:1;

c) subjecting the methane and carbon monoxide rich producer gases to steam
reforming reactions under conditions whereby synthesis gas comprising hydrogen and carbon
monoxide is generated; and
d) subjecting the synthesis gas to a Fischer-Tropsch type reaction under
conditions whereby a liquid fuel is produced.

16. The process as claimed in claim 15 wherein the carbonaceous material is non-
pyrolyzed carbonaceous material.
17. The process as claimed in claim 15 wherein the carbonaceous material comprises
municipal waste, biomass, wood, coal, or a natural or synthetic polymer.
18. The process as claimed in claim 17 wherein the carbonaceous material comprises
biomass.
19. The process as claimed in claim 17 wherein the carbonaceous material comprises
municipal waste which comprises wood or a natural or synthetic polymer.
20. The process as claimed in claim 1 for producing a synthesis gas for use as a gaseous
fuel or as feed into a Fischer-Tropsch type reactor to produce a liquid fuel, the process
comprising:

a) forming a liquid suspension slurry of particles of carbonaceous material in water
to produce a slurry of carbonaceous materials;
b) feeding hydrogen and the suspension slurry into a hydrogasification reactor
without a reaction catalyst at a temperature and pressure sufficient to generate methane and
carbon monoxide rich producer gases, wherein the ratio of water to dry carbonaceous material in
the hydrogasification reactor is at least 2:1,
c) feeding the methane and carbon monoxide rich producer gases from the
hydro-gasification reactor into a steam methane reformer under conditions whereby synthesis
gas comprising hydrogen and carbon monoxide is generated;
d) feeding a portion of the hydrogen generated by the steam methane reformer
into the hydro-gasification reactor as said hydrogen from an internal source; and
e) either utilizing said synthesis gas generated by the steam methane reformer for
process heat or as fuel for an engine to produce electricity, or feeding said synthesis gas into
the Fischer-Tropsch type reactor under conditions whereby a liquid fuel is produced.

21. The process as claimed in claim 20 in which said slurry is formed by grinding said
non- pyrolyzed carbonaceous material in water.
22. The process as claimed in claim 20 in which said carbonaceous material comprises
municipal waste, biomass, wood, coal, or a natural or synthetic polymer.
23. The process as claimed in claim 22 wherein the carbonaceous material comprises
biomass.
24. The process as claimed in claim 22 wherein the carbonaceous material comprises
municipal waste which comprises wood or a natural or synthetic polymer.
25. The process as claimed in claim 20 in which synthesis gas generated by the steam
methane reformer is fed into a Fischer-Tropsch type reactor under conditions whereby a
liquid fuel is produced.

26. The process as claimed in claim 25 wherein said conditions and the relative amounts
of hydrogen and carbon monoxide in the Fischer-Tropsch type reactor are such that said
liquid fuel is produced exothermally.
27. The process as claimed in claim 26 comprising transferring exothermic heat from one
or both of the hydro-gasification reactor and Fischer-Tropsch type reactor to the steam
methane reformer.
28. The process as claimed in claim 26 comprising transferring exothermic heat from the
hydro-gasification reactor and Fischer-Tropsch type reactor to the steam methane reformer.
29. The process as claimed in claim 28 wherein molten salt loops or water-steam loops
are used to transfer said exothermic heat.
30. The process of claim 25 wherein the relative amounts of hydrogen and carbon
monoxide in the synthesis gas fed into the Fischer-Tropsch type reactor are such that said
liquid fuel is substantially cetane.
31. The process as claimed in claim 1 for producing a self-sustaining process for
producing a liquid fuel from carbonaceous feed comprising,

a) forming a liquid suspension slurry of particles of carbonaceous material in
water;
b) feeding hydrogen from an internal source and the suspension slurry into a
hydro-gasification reactor without a reaction catalyst in amounts whereby methane and
carbon monoxide rich producer gases are generated exo-thermally under super-atmospheric
pressure; wherein the ratio of water to dry carbonaceous material in the hydrogasification
reactor is at least 2:1;
c) feeding the methane and carbon monoxide rich producer gases from the
hydro-gasification reactor into a steam methane reformer under conditions whereby synthesis
gas comprising hydrogen and carbon monoxide is generated;
d) feeding a portion of the hydrogen generated by the steam methane reformer,
through a hydrogen purification filter, into the hydro-gasification reactor, the hydrogen
therefrom constituting said hydrogen from an internal source;

e) feeding the remainder of the synthesis gas generated by the steam methane
reformer into the Fischer-Tropsch type reactor under conditions whereby a liquid fuel is
produced exothermally; and
f) transferring the exothermic heat from the hydro-gasification reactor and
Fischer-Tropsch type reactor to the steam methane reformer, whereby said process is
substantially self-sustaining.

32. The process as claimed in claim 31 wherein molten salt loops or water-steam loops
are used to transfer said exothermic heat.
33. The process as claimed in claim 31 wherein said carbonaceous material comprises
municipal waste, biomass, wood, coal, or a natural or synthetic polymer.
34. The process as claimed in claim 33 wherein the carbonaceous material comprises
biomass.
35. The process as claimed in claim 33 wherein the carbonaceous material comprises
municipal waste which comprises wood or a natural or synthetic polymer.
36. An apparatus for producing a synthesis gas for use as a gaseous fuel or as feed into a
Fischer-Tropsch reactor to produce a liquid fuel, comprising:
a source of carbonaceous material and water;
a hydro-gasification reactor; and
a steam pyrolytic reformer;
piping connecting said source of carbonaceous material and water to the hydro-
gasification reactor for feeding carbonaceous material and water thereto to generate methane
and carbon monoxide;
piping connecting the hydro-gasification reactor to the steam pyrolytic reformer for
feeding methane rich producer gases generated in the hydro-gasification reactor to the steam
pyrolytic reformer to generate synthesis gas comprising hydrogen and carbon monoxide;
piping connecting the steam pyrolytic reformer to the hydro-gasification reactor for
feeding a portion of the hydrogen generated by the steam pyrolytic reformer into the hydro-
gasification reactor;

a Fischer-Tropsch reactor and piping connecting the steam pyrolytic reformer to the
Fischer-Tropsch reactor for feeding the remainder of the synthesis gas generated by the steam
pyrolytic reformer into the Fischer-Tropsch reactor to produce a liquid fuel; and
water-steam loops to transfer heat from one or both of the hydro-gasification reactor
and Fischer-Tropsch reactor to one or both of the steam generator and the steam pyrolytic
reformer.
37. The apparatus as claimed in claim 36 for producing a liquid fuel in a substantially
self-sustaining process, comprising:
a hydrogen purification filter;
a Fischer-Tropsch type reactor;
a grinder forming particles of the carbonaceous material;
a receptacle for the particles and water to form a slurry of the carbonaceous particles;
and
a steam generator to heat the slurry and activate the carbon by pyrolysis with
superheated steam.
38. The apparatus as claimed in claim 36 optionally comprising:
a steam generator to provide superheated steam;
piping connecting said source of carbonaceous material and water to the hydro-
gasification reactor for feeding carbonaceous material and water thereto to generate methane
and carbon monoxide in the presence of hydrogen and superheated steam;
piping connecting the hydro-gasification reactor to the steam pyrolytic reformer for
feeding methane and carbon monoxide rich producer gases generated in the hydro-
gasification reactor to the steam pyrolytic reformer to generate synthesis gas comprising
hydrogen and carbon monoxide;
piping connecting the steam pyrolytic reformer to the hydro-gasification reactor for
feeding a portion of the hydrogen generated by the steam pyrolytic reformer into the hydro-
gasification reactor;
piping connecting the steam generator to the hydro-gasification reactor for feeding
superheated steam thereto; and
piping connecting the steam generator to the steam pyrolytic reformer for feeding
superheated steam thereto to react with the methane and carbon monoxide rich producer
gases.

39. The apparatus as claimed in claim 38 wherein a Fischer-Tropsch reactor and piping
connecting the steam pyrolytic reformer to the Fischer-Tropsch reactor for feeding the
remainder of the synthesis gas generated by the steam pyrolytic reformer into the Fischer-
Tropsch reactor to produce a liquid fuel.
40. The apparatus as claimed in claim 39 wherein molten salt loops or water-steam loops
to transfer heat from one or both of the hydro-gasification reactor and Fischer-Tropsch
reactor to one or both of the steam generator and the steam pyrolytic reformer.
41. The apparatus as claimed in claim 39 wherein molten salt loops or water-steam loops
to transfer heat from the hydro-gasification reactor and Fischer-Tropsch reactor to the steam
generator and the steam pyrolytic reformer.
42. The apparatus as claimed in claim 36 for producing a liquid fuel in a substantially
self-sustaining
process, comprising:
a hydrogen purification filter;
a Fischer-Tropsch type reactor;
a grinder forming particles of the carbonaceous material;
a receptacle for the particles and water to form a slurry of the carbonaceous particles;
a steam generator to provide superheated steam;
piping connecting the receptacle to the hydro-gasification reactor for feeding the
slurry thereto to generate methane and carbon monoxide in the presence of hydrogen and
superheated steam;
piping connecting the steam generator to the hydro-gasification reactor for feeding
superheated steam thereto;
piping connecting the hydro-gasification reactor to the steam pyrolytic reformer for
feeding methane and carbon monoxide rich producer gases generated in the hydro-
gasification reactor to the steam pyrolytic reformer to form a synthesis gas comprising
hydrogen and carbon monoxide;
piping connecting the steam pyrolytic reformer to the hydro-gasification reactor
through the hydrogen purification filter for feeding a portion of the hydrogen generated by
the steam pyrolytic reformer into the hydro-gasification reactor; and

piping connecting the steam pyrolytic reformer to the Fischer-Tropsch type reactor for
feeding the remainder of the synthesis gas generated by the steam pyrolytic reformer into the
Fischer-Tropsch type reactor to produce a liquid fuel.
43. The apparatus as claimed in claim 42 wherein molten salt loops or water-steam loops
to transfer heat from one or both of the hydro-gasification reactor and Fischer-Tropsch
reactor to one or both of the steam generator and the steam pyrolytic reformer.
44. The apparatus as claimed in claim 42 wherein molten salt loops or water-steam loops
to transfer heat from the hydro-gasification reactor and Fischer-Tropsch reactor to the steam
generator and the steam pyrolytic reformer.
45. The process as claimed in claim 20, wherein step a) comprises feeding superheated
steam from a steam generator into the hydro-gasification reactor.
46. The process as claimed in claim 45, comprising transferring exothermic heat from one
or both of the hydro-gasification reactor and Fischer-Tropsch reactor to the steam generator.




PROCESS AND APPARATUS FOR CONVERTING CARBONACEOUS MATERIAL
TO ENERGETIC GASES

Abstract of the Invention


A process and apparatus for producing a synthesis gas for use as a gaseous fuel or as feed into
a Fischer-Tropsch reactor to produce a liquid fuel in a substantially self sustaining process. In
one embodiment, a slurry of carbonaceous material in water, and hydrogen from an internal
source, are fed into a hydro-gasification reactor to generate methane rich producer gases
which are fed in to a steam pyrolytic reformer to generate synthesis gas comprising hydrogen
and carbon monoxide. A portion of the hydrogen is used as the internal hydrogen source. The
remaining synthesis gas is either used as fuel to produce electricity and/or process heat or is
fed into a Fischer-Tropsch reactor to produce liquid fuel. In another embodiment of the
invention, carbonaceous material can be heated simultaneously in the presence of both
hydrogen and steam to undergo steam pyrolysis and hydro-gasification in a single step.

Documents:

0768-kolnp-2007 abstract.pdf

0768-kolnp-2007 assingment.pdf

0768-kolnp-2007 claims.pdf

0768-kolnp-2007 correspondence others.pdf

0768-kolnp-2007 description(complete).pdf

0768-kolnp-2007 drawings.pdf

0768-kolnp-2007 form-1.pdf

0768-kolnp-2007 form-13.pdf

0768-kolnp-2007 form-3.pdf

0768-kolnp-2007 form-5.pdf

0768-kolnp-2007 international publication.pdf

0768-kolnp-2007 pct others.pdf

768-KOLNP-2007-(21-11-2011)-ABSTRACT.pdf

768-KOLNP-2007-(21-11-2011)-CLAIMS.pdf

768-KOLNP-2007-(21-11-2011)-CORRESPONDENCE.pdf

768-KOLNP-2007-(21-11-2011)-DESCRIPTION (COMPLETE).pdf

768-KOLNP-2007-(21-11-2011)-DRAWINGS.pdf

768-KOLNP-2007-(21-11-2011)-EXAMINATION REPORT REPLY RECIEVED.PDF

768-KOLNP-2007-(21-11-2011)-FORM-1.pdf

768-KOLNP-2007-(21-11-2011)-FORM-13.pdf

768-KOLNP-2007-(21-11-2011)-FORM-2.pdf

768-KOLNP-2007-(21-11-2011)-FORM-3.pdf

768-KOLNP-2007-(21-11-2011)-OTHER PATENT DOCUMENT.pdf

768-KOLNP-2007-(21-11-2011)-OTHERS.pdf

768-KOLNP-2007-(21-11-2011)-PA-CERTIFIED COPIES.pdf

768-KOLNP-2007-ASSIGNMENT.pdf

768-KOLNP-2007-CORRESPONDENCE.pdf

768-KOLNP-2007-EXAMINATION REPORT.pdf

768-KOLNP-2007-FORM 13.pdf

768-kolnp-2007-form 18.pdf

768-KOLNP-2007-FORM 26.pdf

768-KOLNP-2007-GPA.pdf

768-KOLNP-2007-GRANTED-ABSTRACT.pdf

768-KOLNP-2007-GRANTED-CLAIMS.pdf

768-KOLNP-2007-GRANTED-DESCRIPTION (COMPLETE).pdf

768-KOLNP-2007-GRANTED-DRAWINGS.pdf

768-KOLNP-2007-GRANTED-FORM 1.pdf

768-KOLNP-2007-GRANTED-FORM 2.pdf

768-KOLNP-2007-GRANTED-FORM 3.pdf

768-KOLNP-2007-GRANTED-FORM 5.pdf

768-KOLNP-2007-GRANTED-SPECIFICATION-COMPLETE.pdf

768-KOLNP-2007-INTERNATIONAL PUBLICATION.pdf

768-KOLNP-2007-INTERNATIONAL SEARCH REPORT & OTHERS.pdf

768-KOLNP-2007-OTHERS.pdf

768-KOLNP-2007-PETITION UNDER RULE 137.pdf

768-KOLNP-2007-REPLY TO EXAMINATION REPORT.pdf

768-KOLNP-2007-TRANSLATED COPY OF PRIORITY DOCUMENT.pdf

abstract-00768-kolnp-2007.jpg


Patent Number 256406
Indian Patent Application Number 768/KOLNP/2007
PG Journal Number 24/2013
Publication Date 14-Jun-2013
Grant Date 12-Jun-2013
Date of Filing 02-Mar-2007
Name of Patentee THE REGENTS OF THE UNIVERSITY OF CALIFORNIA
Applicant Address 1111 FRANKLIN STREET, 5TH FLOOR, OAKLAND CA 94607-5200
Inventors:
# Inventor's Name Inventor's Address
1 NORBECK JOSEPH N 600 WEST CENTRAL # 240, RIVERSIDE, CA 92507
2 HACKETT COLIN E 8414 DAISY LANE, RIVERSIDE, CA 92508
PCT International Classification Number F28D 1/00
PCT International Application Number PCT/US2004/025254
PCT International Filing date 2004-08-04
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10/911,348 2004-08-03 U.S.A.