The present application claims priority from PCT/EP2011/064719, filed 26 Aug. 2011, which claims priority from European patent application 10174505.7, filed 30 Aug. 2010, which is incorporated herein by reference.
The present invention relates to a gasification reactor with a heat exchange unit comprising a gas flow channel running from an inlet area to an outlet area and one or more heat exchangers arranged within the gas flow channel, the heat exchangers comprising heat exchange surfaces and associated structures, such as a support structure and deflectors or cover plates to guide the gas flow towards the heat exchange surfaces.
Such gasification reactors can be used for the production of synthetic gas, or syngas. In such a process, carbonaceous feedstock, such as coal, biomass or oil, is partially oxidised in a gasifier unit of the gasification reactor. Subsequently, the syngas flows to the heat exchange unit to be cooled.
U.S. Pat. No. 5,482,110 discloses a heat exchanger for cooling syngas from a partial combustion reactor comprising nested heat exchange surfaces and associated structures in a channel defined by an outer channel wall. The heat exchange surfaces are formed by meandering, helically wound or vertical tubes interconnected to form a gastight wall. The associated structures include a support structure carrying the heat exchange surfaces and a plate blocking the central passage through the central heat exchange surface in order to guide the hot gas as much as possible along the heat exchange surfaces.
When the hot syngas leaves the gasifier unit, it carries fly ash generated as a by-product during the gasification process. Fly ash tends to cause fouling and slag deposits, particularly when the fly ash is still hot and sticky. Fouling and slag deposits on the heat exchange surfaces reduce the cooling efficiency of the heat exchange surfaces. Generally, rappers are used intermittently impacting the heat exchange surfaces to remove foulings and fly ash deposits.
It is an object of the present invention to further prevent efficiency reduction of heat exchangers in the heat exchange section of a gasification reactor by fly ash fouling and slag deposits.
The object of the invention is achieved by providing a gasification reactor with a heat exchange unit comprising heat exchange surfaces and associated structures, wherein the associated structures are provided with one or more fouling protection devices.
Although the contribution of the associated structures to the cooling of the gas is limited, it has surprisingly been found that prevention of slag built-up on these parts does substantially contribute to an overall efficiency of the heat exchanger as a whole.
The one or more fouling protection devices can for instance include one or more soot blowers or blast lances, actively removing slag upon actuation. Good results are obtained with blasters blasting in a radial direction perpendicular to the main gas flow. The blasters can for instance have horizontally directed nozzles in a vertical gas flow channel having an upper inlet and a lower outlet.
Additionally, the one or more fouling protection devices may include flow guiding surfaces, guiding the fly ash bearing gas flow away from the parts to be protected. Such guiding surfaces can for instance be cooled, e.g., they can be formed by one or more interconnected cooling medium conduits, e.g., interconnected parallel or spirally wound conduits or a surface formed by shaped plates with one side forming the guiding surface, optionally having the opposite side thermoconductively connected to cooling medium channels.
It is noted that WO 2010/023306 discloses a quenching vessel cooling hot syngas by using spray conduits provided with a self cleaning arrangement. No heat exchange surfaces with associated structures are used.
The heat exchangers comprise heat exchange surfaces and associated structures. The heat exchange surfaces can, e.g., be built of vertical, meandering or spirally wound cooling medium conduits, which can for instance be interconnected to form a gastight wall. The heat exchange surfaces can for instance be coaxially nested tubular surfaces.
The associated structures of the heat exchangers can for instance include one or more support structures carrying the one or more heat exchangers. Such a support structure can for instance be located at the inlet side of the heat exchange channel, e.g., with the supported heat exchange surfaces hanging down from the support structure. The support structure can be provided with a fouling protection device, such as one or more blasters directed to blast over an upstream surface of the support structure. Where the gas flow in the heat exchange section of a gasification reactor is typically a vertical downward flow, the upstream surface of the support structure will generally be its top surface. Such a support structure can for instance comprise a plurality of radial arms, e.g., extending from a central point, wherein at least a part of the arms are within the scope of the one or more blasters. The blasters can for instance comprise a blast gas supply line extending over the upstream surface of the arm, one longitudinal side of the blast gas supply line being connected to the arm, while the opposite longitudinal side is provided with at least one nozzle oriented into a direction parallel to the longitudinal direction of the blast gas supply line. Optionally, the blaster can have one or more pairs of oppositely directed nozzles.
The associated structures can also include one or more deflectors to guide the gas flow towards the heat exchange surfaces. For instance, if the heat exchange surfaces comprise a set of coaxially nested tubular surfaces, a cover plate is be used to block the central passage in order to prevent that gas flows at a distance from the heat exchange surface which is too large to cool the passing gas effectively. A suitable fouling protection device for such a structure can for instance be a flow guiding surface covering the upstream surface of the cover plate to guide approaching gas alongside the cover plate. Such a flow guiding surface can for instance be a cone or conical flow guide pointing in upstream direction. Such a conical flow guide can for example be formed by one or more conically spiralling cooling medium conduits operatively connected to a cooling medium supply.
Alternatively, or additionally, the cover plate can be arranged within the blasting scope of one or more blasters. The blaster can for instance have one or more nozzles directed to blast in a direction parallel to the upstream surface of the cover plate. This way the one or more blasters blow over the surface to keep it clean in an effective manner. The one or more blasters can for instance have one or more radially extending nozzles branching off under right angles from a lance or central blast gas supply conduit. The conduit or lance can be positioned under right angles with the upstream surface of the cover plate.
Optionally, the associated structures can also include a tubular inner wall defining the channel around the heat exchange surfaces, the inner wall being surrounded by an outer wall. Such an inner wall can for instance be formed by one or more vertical or spirally wound cooling medium conduits interconnected to form a gastight wall structure or membrane. This tubular inner wall will typically be a cylindrical wall but may also have a different type of tubular configuration. The annular space between the inner wall and the outer wall can be in open connection with the lower end of the flow channel enclosed by the inner wall to more or less equalize the pressure at both sides of the inner wall. That way, the inner wall is mainly subjected to thermal stresses while the outer wall is mainly subjected to stresses caused by the gas pressure. Due to this separation of thermal and pressure induced loads the inner and outer channel walls can be constructed in a more economic way.
Such an inner wall or membrane can be provided with a fouling protection device, preferably at the inlet area of the gas flow channel. For instance, one or more radially extending blast lances can extend through the inner wall having nozzles within the gas flow channel. The nozzles can for instance be interconnected by one or more common blasting gas supply lines positioned between the inner wall and the outer wall. Generally the hot gas inlet is not in line with the centreline of the heat exchange channel. It has been found that it suffices if blast lances are provided only in the cross sectional area below the hot gas inlet, e.g., a 180 degrees semi-circular section of the cross sectional area. For instance two common supply lines extending over 90 degrees can be used to feed blast lances arranged over a semi-circular 180 degrees section of the cross sectional area of the tubular inner wall below the hot gas inlet. Other configurations, for instance spanning 270, 300 or 360 degrees or any other angle, can also be used if so desired. By blasting only the parts particularly exposed to slag formation, blasting gas consumption can be saved.
Typically, the cooling medium used is water. That way, the heat exchanger can be used as a steam generator. The generated steam can be used for other useful purposes, thereby contributing to the economic efficiency of the gasification process as a whole.
The blasting gas can for instance be nitrogen. Alternatively, or additionally, other types of blasting gases can be used, if so desired.
An embodiment of the invention will now be described by way of example in more detail with reference to the accompanying drawings.
A heat exchanger 9 is arranged within the channel 7. The heat exchanger 9 comprises a set of, e.g., six nested cylindrical heat exchange surfaces 10, which are schematically represented in the drawing by dash dotted lines. In alternative embodiments, the number of heat exchange surfaces can be less than six or more than six, if so desired. The heat exchange surfaces 10 are formed by spirally wound cooling medium conduits interconnected to form a gastight structure. The nested heat exchange surfaces 10 are coaxial with the inner wall 6 and the outer wall 5. The heat exchanger 9 further comprises associated structures 11, including a support structure 12 and a cover plate 13 blocking the central passage 14 through the inner heat exchange surface 10. The heat exchange surfaces 10 hang down from the support structure 12, which is in turn supported by the inner wall 6.
The associated structures 11, including the support structure 12 and the cover plate 13, are shown in more detail in
The associated structures 6, 12, 13 are provided with fouling protection devices 19. These include blasters 20 on the top edge of each of the arms 15 of the support structure 12. Each blaster 20 comprises a conduit 21 with a closed end 22 and with its lower side connected to the corresponding arm 15, while the opposite top side carries nozzles 23, 24 oriented in a direction parallel to the conduit 21. Nozzles 23 closest to the inner wall 6 are nozzles with a single orifice directed away from the inner wall 6. The other nozzles 24 have two oppositely directed orifices 25, as shown in more detail in
As shown in
A further blast gas supply line 35 leads to radially extending horizontal blast lances 36 crossing the inner wall 6, as shown in plan view in
Number | Date | Country | Kind |
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10174505 | Aug 2010 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2011/064719 | 8/26/2011 | WO | 00 | 6/5/2013 |
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WO2012/028550 | 3/8/2012 | WO | A |
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