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A plasma gasification reactor vessel having a top section with a conical wall extending up from a bottom section, containing a carbonaceous bed into which plasma is injected by plasma torches, to a roof of the vessel is arranged in ways that can contribute to characteristics of gas flow and solids r

A plasma gasification reactor vessel having a top section with a conical wall extending up from a bottom section, containing a carbonaceous bed into which plasma is injected by plasma torches, to a roof of the vessel is arranged in ways that can contribute to characteristics of gas flow and solids residence time that are favorable for thoroughness of reactions and yield of useful reactions products. In some cases, such a conical wall is combined in arrangements with other features such as one or more feed ports arranged to give more uniform distribution including examples with a feed port that has a distributive feed mechanism. The roof of the vessel, in some examples, has vertical outlet ports that include intrusions into the interior volume of the reactor proximate the conical wall of the top section. The configurations of outlet ports with intrusions and the configurations of feed ports for more uniform distribution of feed material are also applicable to reactor vessels with other geometries.

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1. A plasma gasification reactor comprising: a vertically oriented reactor vessel including a bottom section and a top section;the bottom section containing a carbonaceous bed and arranged with one or more plasma torch ports each containing a plasma torch;the top section extending from the bottom se

1. A plasma gasification reactor comprising: a vertically oriented reactor vessel including a bottom section and a top section;the bottom section containing a carbonaceous bed and arranged with one or more plasma torch ports each containing a plasma torch;the top section extending from the bottom section to a roof over and joined with the top section;the top section including an upper portion containing a freeboard region and a lower portion containing a gasification region, the lower portion having an interior surface forming an inverse truncated cone with a narrowest cross-sectional diameter located where the top section is joined to the bottom section, a side wall of the upper portion being oriented at a substantially continuous first angle relative to a vertical axis of the vessel, and a side wall of the lower portion including first and second conical portions being oriented at a substantially continuous second angle relative to the vertical axis of the vessel, wherein the second angle is in a range of between about 5° and about 25° with respect to the vertical axis of the vessel;one or more gas outlet ports from the vessel;one or more feed ports for supply of feed material into the top section, the one or more feed ports being positioned in a cylindrical portion between the first and second conical portions of the side wall of the lower portion of the top section; andone or more tuyeres extending through the top section adjacent to the gasification region for process material including gases and vapors, the tuyeres being located closer to the bottom section of the vessel than the one or more feed ports. 2. The plasma gasification reactor of claim 1, wherein: one or more of the feed ports extend through the cylindrical portion of the side wall of the lower portion of the top section. 3. The plasma gasification reactor of claim 1, wherein: the one or more outlet ports extend through the roof of the vessel. 4. The plasma gasification reactor of claim 1, wherein: the feed ports are configured to receive feed material from a distributive feed supply mechanism, and the distributive feed supply mechanism is controllable to vary the angle in either a horizontal plane or a vertical plane or both a horizontal plane and a vertical plane. 5. The plasma gasification reactor of claim 4, wherein: the distributive feed supply mechanism is controllable for operation to vary the location of feed material to the interior of the top section as to distance from the feed port. 6. The plasma gasification reactor of claim 1, wherein: the one or more feed ports are related to one or more supplies of feed material including one or more of coal, solid waste, and biomass;the one or more tuyeres extending through the top section are related to one or more supplies of process material including one or more of air, oxygen, steam, and water; andthe one or more feed ports supply process material deposited on the carbonaceous bed of the bottom section, to a depth that extends above the tuyeres of the top section, and gaseous reaction products, from reactions of the feed material, process material, and plasma fired carbonaceous bed, include carbon monoxide and hydrogen in a syngas exiting through the outlet ports. 7. The plasma gasification reactor of claim 1, wherein: each feed port is characterized by arrangements for distribution of feed material including a protrusion into the vessel for material to enter other than next to the top section side wall and a distributive feed mechanism for injecting material with force, additional to gravity, into the vessel, wherein the distributive feed supply mechanism is controllable to vary the location of feed material to the interior of the top section as to distance from the feed port; andthe distributive feed mechanism is connected with a controller for operation to vary the location of feed material to the interior of the top section as to both distance and angle from the feed port. 8. The plasma gasification reactor of claim 7, wherein: the distributive feed supply mechanism includes an air blower for applying a mechanical force to the feed material. 9. The plasma gasification reactor of claim 1, wherein: the cylindrical portion of the top section occupies up to about 20% of a vertical height of the top section. 10. The plasma gasification reactor of claim 1, wherein: the side wall of the upper portion of the top section is tilted at an angle of between about 5° and about 25° with respect to the vertical axis of the vessel. 11. The plasma gasification reactor of claim 1, wherein: each of the feed ports includes a protrusion extending into the vessel and angled downward from horizontal at an angle of about 60°. 12. The plasma gasification reactor of claim 11, wherein: the protrusion includes an end from which feed material falls nearer to a center axis of the vessel than to the side wall. 13. The plasma gasification reactor of claim 1, wherein the first angle is smaller than the second angle by 5° or less. 14. The plasma gasification reactor of claim 1, wherein the carbonaceous bed includes at least one of fragmented foundry coke, petroleum coke, or mixed coal and coke, with an average cross-sectional diameter of about 5 cm to about 10 cm. 15. The plasma gasification reactor of claim 1, wherein: a first plurality of the tuyeres extending through the top section are positioned above the bottom section at a location between about 5% and 15% of a distance between the bottom section and the roof; anda second plurality of the tuyeres extending through the top section are positioned above the bottom section at a location between about 10% and 30% of the distance between the bottom section and the roof. 16. A plasma gasification reactor vessel comprising: a bottom section that includes space for a carbonaceous bed and has an exterior wall with one or more plasma torch ports;a top section extending vertically up from the bottom section;the top section including an upper portion containing a freeboard region and a lower portion containing a gasification region, the lower portion having an interior surface forming an inverse truncated cone with a narrowest cross-sectional diameter located where the top section is joined to the bottom section, a side wall of the upper portion being oriented at a substantially continuous first angle relative to a vertical axis of the vessel, and a side wall of the lower portion including first and second conical portions being oriented at a substantially continuous second angle relative to the vertical axis of the vessel, wherein the second angle is in a range of between about 5° and about 25° with respect to the vertical axis of the vessel;a roof covering the top section;one or more gas outlet ports in either or both of the top section and the roof;one or more material feed ports in a cylindrical portion between the first and second conical portions of the side wall of the lower portion of the top section, for supply of feed material into the top section;the top section having one or more tuyeres extending therethrough adjacent to the gasification region for process material including gases and vapors, the tuyeres being located closer to the bottom section of the vessel than the one or more feed ports; anda distributive feed supply mechanism configured to supply feed material to the one or more feed ports, and the distributive feed supply mechanism being controllable to vary a distribution of feed material in the top section. 17. The plasma gasification reactor of claim 16, wherein: at least one of the material feed ports extends through the cylindrical portion of the side wall of the lower portion of the top section. 18. The plasma gasification reactor of claim 16, wherein: the material feed ports include at least one with a distributive feed supply mechanism with a capability of dispersing feed material at varying locations within the top section relative to the position of the material feed port in the side wall. 19. The plasma gasification reactor of claim 18, wherein: the distributive feed supply mechanism is controllable for operation to vary the location of feed material to the interior of the top section as to both distance and angle from the material feed port.