The present invention is directed to a process and system for the generation and treatment of syngas. In particular, the present disclosure is directed to a syngas stream and a method for producing a syngas stream produced by the plasma gasification of waste, including municipal solid waste (MSW).
The effective management and utilization of waste is a global issue. Current waste management techniques, as suggested by regulatory agencies, such as the Environmental Protection Agency (EPA), include source reduction first, recycling and composting second, and, finally, disposal in landfills or waste combustors. Other techniques of managing waste include converting the waste to energy involving processes such as incineration and pyrolysis. There are many types of waste including municipal solid waste, commercial and industrial waste, construction and demolition waste, solid recovered fuel (SRF), refuse derived fuel (RDF), sewage sludge, electronic waste, medical waste, nuclear waste, and hazardous waste. Municipal solid waste (MSW), also called urban solid waste, trash, rubbish, or garbage, mainly comprises household/domestic waste. MSW is generally in solid/semi-solid form and includes paper and card, plastic, textiles, glass, metals, biodegradable waste (kitchen waste, yard sweepings/trimmings, wood waste), inert waste (dirt, rocks) and may include small quantities of miscellaneous materials such as batteries, light bulbs, medicines, chemicals, fertilizers, etc. Typically MSW is found to be predominantly paper/card and kitchen waste, although exact compositions can vary from one region to another depending upon the degree of recycling done by households and transfer stations and/or processing facilities.
One form of waste management includes gasification. Gasification is a process for the conversion of a carbonaceous feedstock such as coal, petroleum, biofuel, biomass, municipal solid waste (MSW), and other wastes into a combustible gas such as synthesis gas. Synthesis gas, commonly referred to as syngas is a mixture of varying amounts of carbon monoxide and hydrogen (CO+H2) and has a variety of applications. The syngas can be used to generate power by combusting directly in a gas turbine, boiler or reciprocating engine and waste heat can be used in the generation of steam which can provide additional power through a steam turbine. Syngas can also be used for the production of hydrogen or liquid fuels or chemicals, which may be used as raw materials in the manufacture of other chemicals such as plastics. Gasification is thus a process for producing value added products and/or energy from organic materials. Typical gas compositions from the gasification of various predominantly carbon-based feedstocks in oxygen are presented in Table 1.
Current waste management techniques, for example as suggested by the EPA, include source reduction first, recycling and composting second, and, finally, disposal in landfills or waste combustors. Other techniques of managing waste include converting the waste to energy using processes such as incineration or pyrolysis. Gasification varies from these processes in that it involves controlled oxygen levels and temperatures in the gasifier, thereby leading to a gas stream richer in syngas.
A particular form of gasification includes plasma gasification. Plasma gasification is a waste treatment technology that uses electrical energy and the high temperatures created by a plasma arc to break down waste into a gaseous product which contains syngas and molten, glass-like by-product (slag) in a vessel called the plasma gasification reactor. Plasma is a high temperature luminous gas that is partially ionized and is made up of gas ions, atoms and electrons. Slag is produced from the vitrification of inorganic mineral matter such as glass and metals which are often contained in waste. Depending on the composition of the MSW and the gasification process, the volatiles typically comprise CO, H2, H2O, CO2, N2, O2, CH4, H2S, COS, NH3, HCl, Ar, Hg, HCN, HF, saturated and unsaturated hydrocarbons (tars) and char (ash).
Whether the purpose of producing syngas is to generate electricity or to produce chemicals, the various impurities present in the raw gas from the gasifier need to be removed prior to usage. The extent of their removal and that of the other components is highly dependent upon the next steps to create a useful product, with very specific requirements needed to maximize the generation of power.
One known process for gasification of municipal solid waste (MSW) as well as other biomass such as wood is disclosed by Faaij et. al. in Biomass and Bioenergy, 12(6), 387-407 (1997), hereinafter “the Faaij reference”. The compositions disclosed in the Faaij reference represent air-fired gasification of MSW and other biomass. However, the crude syngas of Faaij contains 13.98 v/v % CO in wet syngas (16 v/v % CO in dry gas), which is undesirably low compared to desired syngas composition from waste gasification systems. The Faaij reference includes processes that are limited only to air-fired gasification. In addition, the Faaij reference utilizes a specific type of circulating fluidized bed (ACFB type) gasifier from TPS Technology. In addition, the Faaij reference does not disclose COS or HCl as part of the syngas. The NH3 concentration in the Faaij reference is disclosed as 1.00 v/v % (wet basis), corresponding to 11,700 ppm NH3. In addition to the other drawbacks above, the concentration of NH3 in Faaij is undesirably high for known waste gasification and cleanup systems.
Another known syngas production method is disclosed by M. Morris et al. of TPS Termiska Processer AB, NykoEping, Sweden in Waste Management. 1998, 18 (6-8), 557-564, hereinafter “the TPS Termiska reference” where the composition of syngas produced from MSW and biomass has been provided. As in the case of the Faaij reference, the CO concentration is undesirably low for conventional waste gasification and cleanup systems. The composition of CO in the syngas stream disclosed in the TPS Termiska reference is 8.8 v/v % in wet gas (9.74 v/v % in dry gas) and 48 ppm of H2S. The TPS Termiska reference does not disclose COS, HCl, NH3 or HCN. As in the case of the Faaij reference, the TPS Termiska reference does not disclose a plasma gasifier, but is limited to a circulating fluidized bed gasifier. In addition, the TPS Termiska reference is limited to air-fired gasification. In addition to the above drawbacks, the TPS Termiska reference requires pre-sorting and processing of MSW prior to gasification, increasing cost and energy requirements.
Another known gasification process is disclosed by Jae Ik Na et. al. in Applied Energy, 2003, 75, 275-285, hereinafter “the Jae Ik Na reference”. The Jae Ik Na reference discloses gasification of MSW in a fixed bed gasifier.
A known plasma gasification process is disclosed by a publication M. Minutillo et. al. of University of Cassino, Italy in Energy Conversion and Management 50 (2009) 2837-2842, hereinafter “the University of Cassino reference”. The University of Cassino reference discloses information on syngas produced by plasma gasification of refuse derived fuel (RDF). The amount of CO, therefore reducing the H2/CO ratio, disclosed in the University of Cassino reference is undesirably high for conventional waste gasification and cleanup systems. Additionally, the University of Cassino reference does not indicate a syngas composition from MSW. Instead their research involves use of refuse derived fuel (RDF) which is created from MSW by sorting and processing to eliminate as much noncombustible material as possible, thereby significantly increasing the cost and energy associated with the process.
Another plasma gasification process is described in a publication by Vaidyanathan et. al. in Journal of Environmental Management 82 (2007)77-82, hereinafter “the Vaidyanathan reference”. The Vaidyanathan reference discloses plasma gasification of industrial waste and solid waste from the U.S. army. The Vaidyanathan reference does not disclose hydrocarbons, HCl, NH3, HCN, H25 and COS concentrations or particulate loads. In the Vaidyanathan reference, a surrogate solid waste stream is formed to mimic the U.S. army waste stream in their laboratory gasification experiments. The composition of the solid waste stream reported in the Vaidyanathan reference is very different than typical MSW compositions. For example, the paper and card content is about 55 wt % which is much higher than the typical range of 10-35 wt %. Plastic content of the U.S. Army waste is at 25 wt % which is also significantly higher than the typical range of 5-15 wt % in typical MSW.
U.S. Pat. No. 6,987,792 discloses a syngas composition with at least 40-45% H2 and at least 40-45% CO, but fails to disclose any other components.
In addition to the chemical makeup of the syngas, the quality of the syngas stream is addressed in terms of particulate loading and distribution of particulate sizes. More specifically, the two particulate properties for measuring the quality of a syngas stream include the particulate loading and the percent particulate below 1 micron. As one skilled in the art of particulate removal would appreciate, particulates below 1 micron become increasingly difficult to remove. As such, concentrations and/or amounts of particulate below 1 micron provide a measure of the ease or difficulty in which the process stream can be treated.
Examples of particulate loading and sizes are disclosed by the EPA's Emission Standards and Engineering group, who released a two volume report entitled “Control Techniques for Particulate Emissions from Stationary Sources”, hereinafter, the EPA Report. The EPA report provides examples of particulate and size distributions for various industrial applications. Two illustrative applications will be drawn forth for discussion from the incineration of MSW. The first instructive example utilizes the particulate loading and particle size distribution data provided for a typical large scale, stoker like, MSW furnace burning roughly 38,200 kg/hr of solid waste. The furnaces referenced are typical of those built in Europe in the 1940's with five or six in operation in the US in 1982, the year the report was issued. The results show uncontrolled particulate matter (PM) emissions, the particulates present in the stream prior to particulate clean up, having a loading of 2,360 mg/Nm3 and a particle size distribution of less than 20 wt % being smaller than 1 micron in size. Conversely, a second example for a smaller modular system with a staged combustion approach to incineration of MSW yielded particulate loading much higher in small particulates, with greater than 90 wt % of the PM emissions being below 1 micron, with similar loadings of 180-3,340 mg/Nm3. The EPA reports also details particulate loading and particle size distribution for blast furnace offgas. The gas is produced in the making of pig iron and produces a top gas rich in particulate, 27,500 mg/Nm3, in which less than 10 wt % of the particulate is less than 74 microns. Syngas and off gas compositions having high particle loadings and high concentrations of fine particulates below about 1 micron are generally not known in the art. What is desired in the art is a high quality syngas composition formed from gasified waste or plasma gasified waste, that is suitable for efficient cleanup and energy production and does not suffer from the drawbacks of the prior art.
One aspect of the disclosure includes a syngas stream composition comprising up to about 50,000 mg/Nm3 particulates, 5-39 vol % H2, 5-39 vol % CO, 15-50 vol % CO2, 10-60 vol % N2, and 0-2 vol % Argon on a dry basis; and 15-50 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.3-2.0 including at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
Another aspect of the disclosure includes a syngas stream composition comprising between about 5,000 and 29,500 mg/Nm3 or between about 30,500 and about 50,000 mg/Nm3 particulates, 10-30 vol % H2, 15-39 vol % CO, 15-35 vol % CO2, 10-30 vol % N2, and 0-2 vol % Argon on a dry basis; and 15-30 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.6-1.5 including at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
Another aspect of the disclosure includes a syngas stream composition obtained by oxygen-fired gasification comprising up to about 50,000 mg/Nm3 particulates, 5-39 vol % H2, 5-39 vol % CO, 15-50 vol % CO2, 8-30 vol % N2, and 0-2 vol % Argon on a dry basis; and 15-50 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.3-2.0 including at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
In another embodiment of the invention, on a dry basis the syngas stream composition arising from oxygen fired gasification comprises between about 5,000 and 29,500 mg/Nm3 or between about 30,500 and 50,000 mg/Nm3 particulates, 10-35 vol % H2, 15-39 vol % CO, 15-40 vol % CO2, 8-15 vol % N2, and 0-2 vol % Argon; and 15-30 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.6-1.5 and at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
Another aspect of the disclosure includes a syngas stream including gasified waste composition arising from oxygen-fired gasification comprising up to about 50,000 mg/Nm3 particulates, 5-39 vol % H2, 5-39 vol % CO, 15-50 vol % CO2, 8-30 vol % N2, and 0-2 vol % Argon on a dry basis; including 15-50 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.3-2.0 and at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
In another embodiment of the invention, on a dry basis the gasified waste composition arising from oxygen-fired gasification that comprises between about 5,000 and 29,500 mg/Nm3 or between about 30,500 and 50,000 mg/Nm3 particulates, 10-35 vol % H2, 15-39 vol % CO, 15-40 vol % CO2, 8-15 vol % N2, and 0-2 vol % Argon and 15-30 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.6-1.5 and at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
Another aspect of the disclosure includes a syngas stream including the plasma gasified waste composition arising from oxygen-fired gasification comprising up to about 50,000 mg/Nm3 particulates, 5-39 vol % H2, 5-39 vol % CO, 15-50 vol % CO2, 8-30 vol % N2, and 0-2 vol % Argon on a dry basis; and 15-50 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.3-2 and at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
In another embodiment of the invention, on a dry basis the plasma gasified waste composition arising from oxygen-fired gasification comprises between about 5,000 and 29,500 mg/Nm3 or between about 30,500 and 50,000 mg/Nm3 particulates, 10-35 vol % H2, 15-39 vol % CO, 15-40 vol % CO2, 8-15 vol % N2, and 0-2 vol % Argon; and 15-30 vol % moisture on a wet basis. The stream includes a H2/CO ratio that is about 0.6-1.5 and at least 15 wt % of the particulates have an aerodynamic particle diameter of less than or equal to 1 micron.
Another aspect of the present disclosure is a method for generating a syngas composition of the invention via the plasma gasification of waste. Without wishing to be bound by any theory or explanation, it is believed that the composition of the inventive syngas can vary depending upon the composition of the waste employed, the amount of oxygen present during gasification, and the temperature within the gasifier. In general, the higher operating temperature of the plasma gasifier allows for a wide range of feedstocks to be used while producing well-defined syngas compositional ranges. The use of oxygen during gasification can be varied in order to maximize the energy value of the syngas from highly variable waste while maintaining a relatively consistent syngas compositional range For example, increasing the amount of oxygen present during plasma gasification (or using an oxygen-fired gasification) can produce a syngas having increased CO2 levels and lower N2 levels. For the purpose of this invention, the term “oxygen-fired” means that oxygen is introduced into the plasma gasifier for the purpose of aiding in efficiently converting waste into syngas and for improving the energy content of the syngas and, if desired, may used in combination with oxygen and/or air being introduced into the plasma torch or as a shroud around the plasma torch. Oxygen can be introduced into the gasifier as oxygen enriched air or as commercial grade oxygen (e.g., at least about 90 percent purity (mass basis) oxygen). As a representative but not limiting example, the concentration of oxygen in the gasifier could range from about 1 to about 50 percent by mass.
Another aspect of the present disclosure includes a plasma gasified syngas stream arising from oxygen-fired gasification comprising on a dry basis, up to about 50,000 mg/Nm3 particulates, 5-39 vol % H2, 5-39 vol % CO, 15-50 vol % CO2, 8-30 vol % N2, 0-2 vol % Argon, 1000-5000 ppm HCl, 1000-5000 ppm NH3; 15-50 vol % moisture on a wet basis, and a H2/CO ratio that is about 0.3-2.
Another aspect of the present disclosure includes a plasma gasified syngas stream arising from oxygen-fired gasification comprising on a dry basis, between about 5,000 and 29,500 mg/Nm3 or between about 30,500 and 50,000 mg/Nm3 particulates, 10-35 vol % H2, 15-39 vol % CO, 15-40 vol % CO2, 8-15 vol % N2, 0-2 vol % Argon, 1000-5000 ppm HCl, 1000-5000 ppm NH3;15-30 vol % moisture on a wet basis, and a H2/CO ratio that is about 0.6-1.5.
Another advantage of embodiments of the present disclosure is that the waste may be efficiently gasified to form a high quality syngas using a plasma gasifier.
Still another advantage of embodiments of the present disclosure is the unique combination of high particulate load, HCl concentration and NH3 concentration that permit efficient cleanup of the crude syngas.
Still another advantage of embodiments of the present disclosure is the high H2/CO ratio present in the syngas composition.
Still another advantage of embodiments of the present disclosure is that the waste may be controllably and efficiently gasified in the presence of oxygen.
Still another advantage of embodiments of the present disclosure includes shredding of waste without sorting prior to gasification, which reduces or eliminates the need to pre-sort or process waste prior to gasification, which may decrease the cost and energy requirements for the system.
Still another advantage of embodiments of the present disclosure includes a plasma gasifier that does not require drying, pyrolysis, gasification and combustion zones within gasifier, each zone requiring different temperatures, providing for greater simplification of controls and equipment.
The various aspects, embodiments, features and advantages can be employed alone or in combination with each other. Other features and advantages of the present invention will be apparent from the following more detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings which illustrate, by way of example, the principles of the invention.
The present disclosure provides a high quality syngas composition formed from gasified waste or plasma gasified waste that is suitable for efficient cleanup and energy production.
As shown in
The composition of the waste fed into the plasma gasifier affects the composition of the product syngas stream produced. One of the primary types of waste evaluated here is municipal solid waste. Variations in MSW composition significantly alters the composition of the syngas stream produced. The ultimate (i.e. chemical) analysis of various MSW sources was determined and has been reported for various locations. Characterization reports describing the MSW from New York City, overall US and overall UK suggest MSW compositions such as those shown in Table 2.
MSW may comprise 10-35 wt % paper and card, 5-15 wt % plastic, 2-7 wt % textiles, 2-17 wt % glass and metals, 15-30 wt % kitchen waste, 15-25 wt % biomass (includes yard waste, cut grass, wood chips) and 0-20 wt % miscellaneous other materials such as batteries, household sweepings, tires, rubber and leather (Table 3). Ash accounts for roughly 10-25 wt % of MSW, based on this composition.
In some embodiments, the MSW may be pre-sorted prior to firing in the plasma gasifier and comprises 10-50 wt % paper and card, 0-4 wt % plastic, 2-7 wt % textiles, 0-4 wt % glass/metals, 20-35 wt % kitchen waste, 15-30 wt % biomass (includes cut grass, wood chips) and 0-20 wt % miscellaneous materials such as batteries and household sweepings, as shown in Table 4.
The composition of C&D wastes normally includes but is not limited to dirt, stones, bricks, blocks, gypsum wallboard, concrete, steel, glass, plaster, lumber, shingles, plumbing, asphalt roofing, heating, and electrical parts. Yet these materials frequently vary constantly due to the changing nature of construction materials over time. C&D waste may contain about 5 to 30 wt % MSW. Overall, C&D waste is composed mainly of wood products, asphalt, drywall, and masonry; other components often present in significant quantities include metals, plastics, earth, shingles, insulation, and paper and cardboard.
This invention is based on C&D waste that comprises 10-50 wt % wood, 10-60 wt % concrete, 10-30 wt % masonry (bricks, stone, tiles), 5-10 wt % plastic, 5-15 wt % metals, 5-15 wt % paper and card and 0-20 wt % miscellaneous materials such as yard waste (Table 5).
Commercial waste is similar in composition to MSW and comprises paper and card, plastics, textiles, glass, organic waste, metals and other materials. [12] This invention is based on commercial waste that comprises 20-70 wt % paper and card, 5-30 wt % plastic, 0-5 wt % textiles, 2-15 wt % glass and metals, 5-15 wt % organic waste (food, garden), and 0-20 wt % miscellaneous materials such as batteries and sweepings (Table 6).
The plasma gasification process produces a slag stream 117 with molten metals/inorganics from one portion of the plasma gasifier and a product syngas stream 119 from another portion of the plasma gasifier. By “product syngas stream”, it is meant that the syngas stream is the effluent of a waste gasification process, such as plasma gasification, and may comprise CO, H2, H2O, CO2, N2, O2, CH4, H2S, COS, NH3, HCl, Ar, Hg, CxHy, and heavier hydrocarbons (tars), particulates comprising char, ash, and/or unconverted fuel.
To provide a support bed for waste and to enable the flow of slag and transport of gas, optional high carbon-containing feedstocks 115, such as coke or coal feeds may be provided. Steam 109 may also be added to aid in the transport of gas or the flow of slag or for temperature moderation.
Certain embodiments of the present disclosure are directed to the composition of a heterogeneous syngas stream produced by the plasma gasification of waste, especially municipal solid waste (MSW) and commercial waste. The syngas exits the plasma gasifier at high temperature and is first cooled in the gasifier or in an elbow duct directly connected to the gasifier. Cooling in the freeboard region of the gasifier may optionally be considered as part of the cooling in the gasifier. The syngas is then cooled further by performing a quench step along with particulate and other impurity removal. As it comes out of the gasifier, the cooled stream contains several gas-phase components in addition to CO and H2 including NH3, HCl, CO2, N2, Ar, COS, H2S, inerts, water vapor and hydrocarbons. Other impurities present in the gas stream include metallic impurities such as mercury and a large amount of particulate matter. This invention identifies the composition of the gas stream at the exit of the plasma gasifier. The unique properties of this stream are important in identifying an appropriate clean-up train required to purify this stream so that the syngas may be utilized for power generation using a gas turbine, reciprocating engine, or internal combustion engine. Some unique features of the product syngas stream are the high particulate content and high concentrations of ammonia and HCl. HCl and ammonia are present in comparable concentrations and thereby allow for unique clean-up technology such as co-scrubbing. The H2S and COS compositions also provide a distinctiveness to the gas stream.
As shown in
The clean syngas stream 121 may be a clean syngas stream for power production, which is fed to a power generation system 107 wherein the syngas is combusted or otherwise utilized to generate power. In one embodiment of the invention, the product syngas stream is fed into a clean-up system and power generation system that are designed to maximize the production of power from gasified waste. In other embodiments, the power generation system 107 may be replaced with a chemical or liquid fuel manufacturing process such as the Fischer-Tropsch process, a hydrogen separation unit or series of units to produce clean hydrogen, or other unit or device that utilizes syngas for chemical synthesis or other process that utilizes CO and/or H2.
An exemplary but not limiting arrangement of plasma gasifier for use with the present disclosure includes a vessel of a vertical configuration, having a bottom section, a top section, and a roof over the top section. In certain embodiments, the bottom section, which may be cylindrical, contains a carbonaceous bed into which one or more plasma torches inject a plasma gas to create an operating temperature of at least about 600° C. (for example up to about 2000° C.). Although the plasma torches themselves can reach temperatures of about 2000 to about 3000° C. or higher, the temperature that the waste or feedstocks are subjected to can range from about 800 to about 1500° C. range and temperature of the syngas exiting the gasifier can range in temperature of about 800 to about 1200° C. The top section extends upward from the bottom section as a conical wall, substantially continuously without any large cylindrical or other configured portions, to the roof of the vessel, the conical wall being inversely oriented, i.e., its narrowest cross-section diameter being at the bottom where it is joined with the bottom section, and is sometimes referred to herein as having the form of a truncated inverse cone. United States Patent Application Publication 2010/0199557A1 discloses a plasma gasification reactor, and is hereby incorporated by reference.
One desirable aspect of the invention is that the higher temperatures employed for gasification enable a higher percentage of syngas to be produced per unit waste with less tars and other hydrocarbons by-products thereby permitting more efficient power production with the resulting syngas. For example, the inventive syngas can contain less than about 14% tar and other hydrocarbons.
Another exemplary, but not limiting, arrangement of plasma gasifier for use with the present disclosure includes a bottom section with a coke bed in which plasma torches and a mix of oxygen/air/steam tuyeres are directed at the coke bed. Above the bottom section is a lower feed bed section in which oxygen/air/steam tuyeres are located at least one level above the coke bed and where flows are directed at the bed of waste material that rests on the coke bed. The lower feed bed section includes side feed ports. Above the lower feed bed section is a freeboard section which provides residence time for hot gas. Above the freeboard section within the gasifier is an optional partial cooling section which cools the gas via a water only spray, via steam injection, or via a combination of the two. An optional recycle of syngas or other fluid may also be used to cool the syngas within the gasifier. Above the partial cooling section in the gasifier is an elbow duct.
The syngas formed by the gasifier has a unique composition of the syngas stream produced by the plasma gasification of waste, especially municipal solid waste (MSW). The syngas exits the plasma gasifier at high temperatures such as 800-1200° C. (˜1500-2200° F.), and may optionally be cooled at the exit of the gasifier to about 1000° C., 900° F., or even 800° F., and is then cooled to much lower temperatures by performing a quench. Optionally, a radiant cooler may be used for waste heat recovery.
The product syngas stream from a plasma gasifier processing waste and operating in the air-fired or oxygen-fired modes, has a temperature of up to about 1500-2200° F. and can contain up to about 50,000 mg/Nm3 or from about 30,500 to 50,000 mg/Nm3 or from 5,000 to 29,500 mg/Nm3 particulates. In addition, the particle size distribution of the particulate matter present in the syngas stream from the gasifier includes at least 15 wt %, or at least 30 wt %, or at least 50 wt % of the particulate having an aerodynamic particle diameter less than or equal to 1 micron. In one embodiment, the plasma gasifier processes a waste stream that comprises of 40-100 wt % MSW and commercial waste, less than about 15 wt % industrial waste, less than about 30 wt % construction and demolition (C&D) waste and less than about 15 wt % hazardous waste and is operated in the air-fired mode. On a dry basis, the gas also comprises 4-39 vol % H2, 5-39 vol % CO, 15-50 vol % CO2, 10-60 vol % N2 and 0-2 vol % Argon. The gas stream may contain 15-50 vol % moisture. The H2/CO ratio is about 0.3-2 as shown in Table 7. The post-quench syngas stream is saturated in water.
In another embodiment of the invention, on a dry basis the gas comprises 10-30 vol % H2, 15-39 vol % CO, 15-35 vol % CO2, 10-30 vol % N2, and 0-2 vol % Argon and the H2/CO ratio is about 0.6-1.5.
In the oxygen-fired mode, the product syngas stream comprises 15-50 vol % moisture. On a dry basis, the gas also comprises 5-39 vol % H2, 5-39 vol % CO, 15-50 vol % CO2, 8-30 vol % N2 (due to air ingress) and 0-2 vol % Argon. The H2/CO ratio is about 0.3-2 as shown in Table 7. The post-quench syngas stream is saturated in water.
In another embodiment of the oxygen-fired mode, the product syngas stream comprises 15-30 vol % moisture. On a dry basis, the gas also comprises 10-35 vol % 15-39 vol % CO, 15-40 vol % CO2, 8-15 vol % N2 (due to air ingress) and 0-2 vol % Argon. The H2/CO ratio is about 0.6-1.5 as shown in Table 7. The post-quench syngas stream is saturated in water.
The product syngas stream also includes small amounts of methane and other gaseous hydrocarbons. On a dry basis, 0-10 vol % CH4 and 0-4 vol % saturated or unsaturated hydrocarbons other than CH4 may be found. Any hydrocarbons in the solid phase are likely removed in the quench step.
The crude syngas stream contains between about 1000 and about 3000 ppm or between about 1000 and 5000 ppm HCl and between about 1000 and about 3000 ppm or between about 1000 and 5000 ppm NH3, quantities which are higher than typically observed in syngas.
Mercury is present in trace quantities in the product syngas stream as well as the quenched syngas stream. Up to about 250 ppm mercury may be present in the streams. Sulfur is present primarily in the form of H2S and COS in the syngas stream. Typically about 500-2000 ppm of sulfur is expected in the product syngas stream. 1-20% of the sulfur is present in the form of COS while the balance is present as H2S.
As shown in
Syngas exits the quench step at a temperature depending on the quench methodology and operating conditions. The output temperature can be between 100° F. (38° C.) and 212° F. (100° C.).
In one embodiment of the present disclosure, the wet quench is performed with a high volume of water, such as from 200 to 300 m3/h, to allow rapid cooling.
Dioxin and furan formation may occur when process temperatures are in the range of from about 250° C. (482° F.) to about 350° C. (662° F.) in the presence of oxygen, when carbon is in the particulates, and when all of these are present at adequate residence time to provide the conditions sufficient to produce dioxin and/or furan. Wet quenching may be performed under controlled temperatures, such as temperatures below 250° C. (482° F.), at residence times and controlled oxygen content to prevent dioxin/furan formation.
In another embodiment of the present disclosure, dry quenching replaces or supplements the wet quenching process. Dry quenching may be performed by evaporative cooling of water at controlled temperatures. In another embodiment of the present disclosure, quenched syngas stream 207 can be recycled to exchange heat with the product syngas stream 119 to reduce the gas temperature of the syngas stream 119.
Standard conditions for the plasma gasification of waste involve high temperatures, a pressure slightly above, at, or slightly below atmospheric pressure, and air and/or oxygen input to the gasifier. The waste may or may not be pre-sorted prior to gasification to remove recyclable materials such as glass, plastic, and metals, and may be co-fired with high carbon-containing feedstocks such coal/metallurgical coke/petroleum coke, if needed. As shown in
The hot, particle-laden gas from the plasma gasifier is first cooled in a preliminary cooling step which may occur either in the gasifier or in an elbow duct directly connected to the gasifier. The crude, slightly cooled syngas is further cooled in a quench step. As shown in
In another embodiment of the invention, dry quenching replaces or supplements the wet quenching process. Dry quenching may be performed by evaporative cooling of water at controlled temperatures. In another embodiment of the invention, cooler downstream syngas can be recycled to exchange heat with the hot syngas to significantly reduce the syngas temperature. In a further embodiment, steam maybe added to the hot syngas to reduce the syngas temperature.
As shown in
The composition of the syngas was obtained using the results from an in-line Mass Spectrometer and these results were verified by taking bomb samples of the syngas after it exited the gasifier and analyzing them using Gas Chromatography.
Particulate analyses were carried out per modified EPA Method 5 for Particulate Loading and via GARB 501 for the Particle Size Distribution (PSD).
Particle Loading—Filterable Particulate Matter (FPM)—EPA Method 5 (Modified)
Sampling using USEPA Method 5 procedures was modified to collect filterable particulate matter (FPM) emissions at the approximate syngas temperature, rather than at EPA Method 5 specified 248±25° F. All samples were analyzed according to analytical procedure in EPA Method 5B; the filters were baked at 160° C.
Particle Size Distribution (PSD)—CARB 501
Particulate matter was withdrawn isokinetically from the source and segregated by size in an in-situ cascade impactor at the sampling point exhaust conditions of temperature, pressure, etc. The resulting index of the measured particle size is traditionally separated by the particle diameter collected with 50% collection efficiency by each jet stage, and this diameter is usually called the “cut diameter” and is characterized by the symbol “D50.” The aerodynamic cut diameter is the diameter of an equivalent unit density sphere which would be collected with 50% efficiency by the specific impactor jet stage. The mass of each size fraction is determined gravimetrically. Particle size determination testing varies from standard mass testing in that too much material can be collected, voiding the sample, as well as too little material, so there is no set test length. A target minimum total sample catch of 10 milligrams was used, based on the Method 5 (Modified) data. The typical sample rate for particle sizing is 0.3 to 0.5 cubic feet per minute (cfm).
A waste comprising refuse derived fuel was fired in a plasma gasifier in oxygen-fired mode in the presence of metallurgical coke and produces a product syngas stream containing 32,000 mg/Nm3 of particulates, 65 wt % of the particles were less than 1 micron in size, at a temperature of 1800° F. (982° C.) and a pressure of 0 psig. The concentrations on a dry basis of H2, CO, CO2, and N2 are 28 v/v %, 26 v/v %, 29 v/v %, and 16 v/v %, respectively with a moisture content of 20 v/v %. The concentrations of NH3 and HCl are 1800 ppm and 1800 ppm respectively. The crude syngas stream contains 1500 ppm H2S and 170 ppm COS.
A waste comprising refuse derived fuel was fired in a plasma gasifier in oxygen-fired mode in the presence of metallurgical coke and produces a product syngas stream containing 28,000 mg/Nm3 of particulates, 35 wt % of the particles were less than 1 micron in size, at a temperature of 1800° F. (982° C.) and a pressure of 0 psig. The concentrations on a dry basis of H2, CO, CO2, and N2 are 17 v/v %, 17 v/v %, 38 v/v %, and 28 v/v %, respectively with a moisture content of 22 v/v %. The concentrations of NH3 and HCl are 1800 ppm and 1800 ppm respectively. The crude syngas stream contains 1500 ppm H2S and 170 ppm COS.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
This application claims the benefit of U.S. Application No. 61/412,078, filed on Nov. 10, 2010. The disclosure of Application No. 61/412,078 is hereby incorporated by reference.
Number | Date | Country | |
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61412078 | Nov 2010 | US |
Number | Date | Country | |
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Parent | 13293330 | Nov 2011 | US |
Child | 14083732 | US |