This invention relates to the field of energy transformation and more particularly to a system for extracting a usable fuel from another material such as coal.
The use of certain materials to provide energy for useful work is often precluded by the format of the materials and/or the byproducts of using such materials. For example, in the early 1900s, coal was used as a source of heat in individual homes. The format of coal provides several challenges as it is a solid and has considerable mass. This precludes distributing coal to homes in an automated way as, for example, natural gas is distributed today. In those days, coal was delivered in dump truck and loaded into basement bins through a chute, where the homeowner had to then shovel the coal from the bin into the furnace for heating and hot water production. Even if the economics of such distribution made the use of coal desirable, there still exist several issues that are difficult to overcome in individual households such as the dust created from the delivery and movement of coal and pollution caused in the process of burning the coal in the individual furnaces. The same or similar issues are presented by burning wood, oil, or other liquid fuels in individual homes.
Consider the issues with portable fuel supplies, as used by automobiles, trucks, airplanes, trains, ships, etc. Again, in the early 1900s, coal and wood were used directly as an energy source to move trains and ships, but such is not practical for smaller vehicles such as automobiles and, definitely not usable in aviation. Further, even in larger-scale vehicles (e.g. ships and trains), the distribution/delivery issues along with pollution issues lessens the usefulness of a solid fuel such as coal.
Today, most portable applications such as vehicles derive energy either from electricity or a liquid fuel such as gasoline, diesel, or natural gas. Likewise, most distributed uses of energy (e.g. homes and businesses) are delivered as electricity or in liquid form (e.g. oil/diesel, natural gas, propane). It has been found that delivery and distribution of a liquid fuel is more efficient than of a solid fuel, as in liquid form, the fuel can be easily moved through pipes and hoses and fed directly to homes or delivered in trucks to distribution centers (e.g. gas stations, propane tanks) for refiling of individual tanks (e.g. vehicle tanks, home storage tanks).
Unfortunately, this precludes the use of many readily available and lower-cost energy sources such as coal, wood, landfill material, etc.
What is needed is a system that will convert such energy sources into a usable gas such as syngas.
In one embodiment, a system for gasification of a material is disclosed including a plasma generator interfaced to a reaction chamber. A feedstock is fed into a plasma jet created by the plasma generator and is gasified by the high temperatures of the plasma jet. The gas produced is then collected, filtered, and utilized, for example, in generating of electricity. Likewise, extra heat produced by the system is also used to generate electricity or other heating purposes.
In another embodiment, a system for gasification of pulverized coal is disclosed including a plasma generator interfaced to a reaction chamber. The coal is pulverized and then fed into a plasma jet created by the plasma generator. The coal is gasified by the high temperatures of the plasma jet and the gas produced is collected, filtered, and utilized, for example, in generating of electricity. Likewise, extra heat produced by the system is also used to generate electricity or other heating purposes.
In another embodiment, a system for gasification of a material is disclosed including a plasma generator interfaced to a reaction chamber. A feedstock such as pulverized coal along with a carrier gas or water is fed into a plasma jet created by the plasma generator and is gasified by the high temperatures of the plasma jet. The gas produced is analyzed and a controller adjusts the feed rates of the feedstock and carrier gas/water and/or the operation of the plasma generator to control the gas generation. The gas is then collected, filtered, and utilized, for example, in generating of electricity. Likewise, extra heat produced by the system is also used to generate electricity or other heating purposes.
The invention can be best understood by those having ordinary skill in the art by reference to the following detailed description when considered in conjunction with the accompanying drawings in which:
Reference will now be made in detail to the presently preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. Throughout the following detailed description, the same reference numerals refer to the same elements in all figures.
Throughout this description, an exemplary input material of coal is used for clarity and brevity reasons. The described system is intended to be used with any liquid or solid material, including coal (granular coal), wood (e.g. sawdust), etc.
Referring to
Again, granular/particulate coal 3 (e.g. pulverized coal, powdered coal, etc.) is used in the examples as a feedstock. In
In some embodiments, there is a cooling coil 18 that is fed water from a source of water connected to water input 16. It is anticipated that, in some embodiments, a portion of any steam or heated water produced from the cooling coil 18 is also injected into the plasma jet 28, further reducing an amount of energy input, while in some embodiments, a portion of any steam or heated water produced from the cooling coil 18 is used for other energy needs, such as producing electricity, heating buildings, etc.
The syngas 7 that flows from the reaction chamber 5 is routed through a chiller (not shown) for cooling and heat recovery. For example, sulfur is removed by catalytic hydrolysis of COS to H2S followed by adsorption or the use of an acid gas removal system. The syngas 7 is later compressed, filtered 86, and purified to remove sulfur compounds. The syngas 7 (purified) is, for example, later combusted for the generation of electricity 100.
The syngas 7 that is produced is analyzed by a gas analyzer 88 and the output of the gas analyzer 88 is read by the system controller 89 to control the operation of the plasma gun 20 and the input rates of the feedstock (e.g. granular/particulate coal 3) and the carrier gas.
The plasma gun 20 includes an electric arc struck between the cathode 24 and the anode 26 of the plasma gun in the presence of a processed gas. The arc ionizes the processed gas to form the plasma jet 28 (plasma plume). The plasma jet 28 emanates from the plasma gun 20 at a velocity of, for example, 400 meters per second and at a temperature of from 10,000° K to 20,000° K. Granular/particulate coal 3 and other materials (e.g. carrier gas, oxygen, water) used in the process of gasification enter from the inputs 12/13 into the plasma jet 28. The resulting gas (e.g. syngas 7) exits through a gas output tube 30 for storage and later use. When granular/particulate coal 3 is used in the gasification system 10, the gas emanating from the gas output tube 30 is syngas 7 (synthetic natural gas). A byproduct of the granular/particulate coal 3 that is exposed to the plasma jet 28 is coal slag 42 that falls onto a crucible 50. Coal slag 42 remaining on the crucible remains in contact with the plasma jet 28 and continues to gasify; then as the coal slag 42 accumulates, the coal slag 42 eventually overflows the crucible 50 and falls into a cooling bath 60 (e.g. cooling water). Periodically, accumulated coal slag 42 is emptied from the cooling bath 60 using a pair of valves 62/64, for example, knife valves. In operation, the second valve 64 is closed and the first valve 62 is opened allowing the accumulated coal slag 42 to fall into an area between the first valve 62 and the second valve 64. Then the first valve 62 is closed and the second valve 64 is opened, allowing the accumulated slag 42 to exit from the area between the first valve 62 and the second valve 64.
As it is anticipated that temperatures within the reaction chamber 5 will approach between 10,000° K and 20,000° K, a requirement for cooling is anticipated. For this, the reaction chamber 5 is water-cooled by a cooling coil 18 (or any other circulation system) that surrounds the plasma jet 28 that receives water from a water input pipe 40 and emits steam out of a steam output pipe 17. Although not required, it is fully anticipated that as heat is extracted from the reaction chamber 5 by the cooling coil 18, the steam that is generated is used to generate additional electricity 100 by use of a turbine 80 and generator 82.
For completeness, the gasification system 10 is shown on a stand 70, though any mounting system is anticipated.
The plasma gun 20 is shown in detail in
It is anticipated that temperatures within the reaction chamber 5 will reach, for example, 10,000 degrees Kelvin. For example, in
Equivalent elements can be substituted for the ones set forth above such that they perform in substantially the same manner in substantially the same way for achieving substantially the same result.
It is believed that the system and method as described and many of its attendant advantages will be understood by the foregoing description. It is also believed that it will be apparent that various changes may be made in the form, construction and arrangement of the components thereof without departing from the scope and spirit of the invention or without sacrificing all of its material advantages. The form herein before described being merely exemplary and explanatory embodiment thereof. It is the intention of the following claims to encompass and include such changes.
This application claims the benefit of U.S. provisional application No. 62/542,689 filed on Aug. 8, 2018, the disclosure of which is incorporated by reference.
Number | Date | Country | |
---|---|---|---|
62542689 | Aug 2017 | US |