Patent Application
20160223187
The invention relates to a method for treating process gas flowing from a furnace space of a pyrometallurgical furnace into a waste heat boiler that is in fluid communication with the furnace space of the pyrometallurgical furnace at a connecting aperture as defined in the preamble of independent claim 1.
The invention also relates to an arrangement for treating process gas flowing from a furnace space of a pyrometallurgical furnace into a waste heat boiler that is in fluid communication with the furnace space of the pyrometallurgical furnace at a connecting aperture as defined in the preamble of independent claim 10.
By a pyrometallurgical furnace is in this context meant for example, but not excluding other types of pyrometallurgical furnaces, a suspension smelting furnace, a top submerged lance furnace i.e. a TSL furnace, or an electrical furnace.
In order to recover metals, such as copper, nickel or lead, from sulfidic raw materials containing said materials, for instance from ores or concentrates, a suspension smelting method may be applied, where heat amounts contained in finely divided sulfidic raw materials are utilized. In such suspension smelting method sulfidic raw material and oxygen-containing gas, such as air, oxygen-enriched air or oxygen is fed into a reaction shaft of a suspension smelting furnace. In addition, for instance flue dust recovered and recirculated from the process gases of the suspension smelting furnace, as well as metallurgic slag-forming agent, flux, is additionally fed into the reaction shaft of the suspension smelting furnace. In the reaction shaft of the suspension smelting furnace, the solid and gaseous feed materials react with each other, so that in the bottom part of the suspension smelting furnace, i.e. in the settler, there are formed at least two molten phases, a slag phase and a matte phase containing the metal to be recovered. The molten phases that are formed in the bottom part of the suspension smelting furnace are removed from the suspension smelting furnace at regular intervals. Sulfur dioxide containing process gases created in the reaction shaft of the suspension smelting furnace are conducted, via the settler, to an uptake shall of the suspension smelting furnace, and from the uptake shaft further to a waste heat boiler connected to the suspension smelting furnace, in which waste heat boiler the process gases from the suspension smelting furnace are cooled, and at the same time the solids, i.e. flue dust, contained in the gas are removed.
When the suspension smelting furnace process gases are transferred from the uptake shaft of the suspension smelting furnace to the waste heat boiler, the flowing direction of the gases is changed from an essentially vertical direction to an essentially horizontal direction. Moreover, because the flowing area of the connecting aperture between the uptake shaft and the waste heat boiler is made essentially smaller than that of the uptake shaft in order to reduce the heat losses from the suspension smelting furnace, contacts of sulfur dioxide bearing process gases with the walls of the suspension smelting furnace cannot be avoided. Further, because the temperature of the process gases is dropped towards the top part of the uptake shaft of the suspension smelting furnace, molten particles contained in the process gases start to solidify, and when touching the uptake shaft walls, they attach to the wall, particularly in the vicinity of the connecting aperture between the uptake shaft and the waste heat boiler. Thus, in the vicinity of the connecting aperture, there is accumulated dust accretions or build-up that obstruct the flowing of the process gases and must therefore be broken apart. Removal of such build-up can be hazardous and required a shutdown.
Publication WO 02/01131 presents an apparatus for mechanically breaking up and detaching dust accretions created by process gases and accumulated on the inner walls of a suspension smelting furnace and/or a waste heat boiler permanently connected to the suspension smelting furnace. In this known solution, on the outer surface of the wall of the suspension smelting furnace and/or the waste heat boiler, in the vicinity of the connecting point of the suspension smelting furnace and the waste heat boiler, there is installed at least one striker device, whereby there can be created a mechanical impact effect and mechanical contact between the apparatus and at least one of the dust accretions.
Publication U.S. Pat. No. 6,228,144 presents a method for operating waste heat boiler in flash-smelting furnace. In a copper flash-smelting works, forced oxidation of dust is prevented, adhesion of dust to a boiler water tube is reduced, and on-line ratio and productivity index is improved. The temperature at the WHB radiation section outlet is greatly reduced and the atmosphere within the WHB radiation section is controlled by blowing the mixed gas of nitrogen gas and air from the feed aperture established in the wall into the boiler radiation section of the waste heat boiler of the flash-smelting furnace in a copper flash-smelting works.
The object of the invention is to provide a method and an arrangement for treating process gas flowing from a furnace space of a pyrometallurgical furnace into a waste heat boiler that is in fluid communication with the furnace space of a pyrometallurgical furnace at an opening with the aim to prevent or at least to minimized the formation of build-up in the connecting aperture between the furnace space of the pyrometallurgical furnace and the waste heat boiler.
The method of the invention is characterized by the definitions of independent claim 1.
Preferred embodiments of the method are defined in the dependent claims 2 to 9.
The arrangement of the invention is correspondingly characterized by the definitions of independent claim 10.
Preferred embodiments of the arrangement are defined in the dependent claims 11 to 18.
The invention is based on providing the region of the connecting aperture between the furnace space of the pyrometallurgical furnace and the waste heat boiler with a gas blowing means for blowing gas into process gas flowing from the furnace space of the pyrometallurgical furnace into the waste heat boiler and on blowing gas with the gas blowing means into process gas flowing from the furnace space of the pyrometallurgical furnace into the waste heat boiler.
The invention provides for several advantages. Especially in suspension smelting furnaces the formation of build-up in the connecting aperture between the uptake shaft of a suspension smelting furnace and the waste heat boiler is prevented or at least reduced, because the gas cools down or extinguish the burning dust particles in the process gases quickly before they hit the surfaces of the connecting aperture and begin to form build-up. For example uneven burning of concentrate, feed disturbances or changes in physical or chemical properties of the feed in a suspension smelting process can lead to delayed burning of concentrate all the way through the waste heat boiler.
Especially in suspension smelting furnaces the gas can also be used for flushing the lower part of the connecting aperture between the uptake shaft of a suspension smelting furnace and the waste heat boiler and keep it cleaner from build-up and thereby improve the installation of a damper for temporary closing the connecting aperture between the uptake shaft of a suspension smelting furnace and the waste heat boiler.
Especially in suspension smelting furnaces the flue dust in process gas coming from the uptake shaft of the suspension smelting furnace off-gas must be sulfatized in order to achieve good flowing ability of the dust. The gas that is fed in the region of the connection aperture can also be used for sulfatizing particles in the process gas by mixing sulfatizing gas with the process gas. With the arrangement it is possible to eliminate or to reduce the amount of sulfation air nozzles in the waste heat boiler. Oxidic or sulfidic dust reacts together SO3 and/or with SO2 and oxygen from the sulfatation gas and forms metal sulfates.
In the following the invention will described in more detail by referring to the figures of which
The invention relates to a method and to an arrangement for treating process gas flowing from a furnace space of a pyrometallurgical furnace 1 into a waste heat boiler that is in fluid communication with the furnace space (not marked with a reference numeral) of the pyrometallurgical furnace 1 at a connecting aperture.
The pyrometallurgical furnace 1 that is used in the method or in the arrangement can for example be any one of the following: a suspension smelting furnace 1a such as a flash smelting furnace or a flash converting furnace, a top submerged lance furnace 1b, and an electrical furnace 1c.
First the method and some preferred embodiment and variants thereof will be described in greater detail.
The method comprises a providing step for providing the region of the connecting aperture 6, preferably the connecting aperture 6, between the furnace space of the pyrometallurgical furnace 1 and the waste heat boiler 2 with a gas blowing means 7 for blowing gas into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
The method comprises a blowing step for blowing gas with the gas blowing means 7 into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
The method comprises preferably, but not necessarily, using as gas in the blowing step at least one of the following: air, nitrogen-enriched air, oxygen-enriched air and inert gas such as nitrogen or argon.
The providing step of the method comprises preferably, but not necessarily, providing a gas blowing means 7 in a lower region of the connecting aperture 6, and the blowing step of the method comprises preferably, but not necessarily, blowing gas into the process gas 8 from below into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
The providing step of the method comprises preferably, but not necessarily, providing a gas blowing means 7 in at least one side region of the connecting aperture 6, and the blowing step of the method comprises preferably, but not necessarily, blowing gas into the process gas 8 from the side into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
The providing step of the method comprises preferably, but not necessarily, providing a gas blowing means 7 in an upper region of the connecting aperture 6, and the blowing step of the method comprises preferably, but not necessarily, blowing gas into the process gas 8 from above into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
The providing step of the method comprises preferably, but not necessarily, providing a gas blowing means 7 having an elongate configuration and provided with several gas discharge openings 9 along the elongated configuration, and arranging the gas blowing means 7 to extend in the transverse direction of the flow of process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2. The gas blowing means 7 can for example be provided with a plurality of gas discharge openings 9.
In case the pyrometallurgical furnace 1 in the method is a suspension smelting furnace 1a, the method may include adjusting the amount of gas that is blown into process gas 8 flowing from the uptake shaft 5 of a suspension smelting furnace 1a into the waste heat boiler 2 based on a calculated sulfatization need of the process gas 8.
In case the pyrometallurgical furnace 1 in the method is a suspension smelting furnace 1a, the method may include adjusting the amount of gas that is blown into process gas 8 flowing from the uptake shaft 5 of a suspension smelting furnace 1a into the waste heat boiler 2 based on measured residual oxygen content in the process gas 8.
The providing step of the method comprises preferably, but not necessarily, providing a gas blowing means 7 at least partly in the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
The blowing step of the method comprises preferably, but not necessarily, blowing in the blowing step gas with the gas blowing means 7 into the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
The blowing step of the method comprises preferably, but not necessarily, blowing blowing step gas with the gas blowing means 7 into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c into the waste heat boiler 2 in the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
The blowing step of the method comprises preferably, but not necessarily, blowing blowing step gas with the gas blowing means 7 from below into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c into the waste heat boiler 2 in the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
Next the arrangement some preferred embodiments and variants of the arrangement will be described in greater detail.
In the arrangement the region of the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1 and the waste heat boiler 2 is provided with a gas blowing means 7 for blowing gas into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
The gas blowing means 7 are preferably, but not necessarily, configured for blowing at least one of air, nitrogen-enriched air, oxygen-enriched air and inert gas such as nitrogen or argon.
Gas blowing means 7 are preferably, but not necessarily, provided in a lower region of the connecting aperture 6, and gas blowing means 7 provided in the lower region of the connecting aperture 6 are preferably, but not necessarily, configured for blowing gas into the process gas 8 from below into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
Gas blowing means 7 are preferably, but not necessarily, provided in at least one side region of the connecting aperture 6, and gas blowing means 7 provided in a side region of the connecting aperture 6 are preferably, but not necessarily, configured for blowing gas into the process gas 8 from a side into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
Gas blowing means 7 are preferably, but not necessarily, provided in an upper region of the connecting aperture 6, and gas blowing means 7 provided in the upper region of the connecting aperture 6 are preferably, but not necessarily, configured for blowing gas into the process gas 8 from above into process gas 8 flowing from furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2.
The gas blowing means 7 may, as shown in
In case the pyrometallurgical furnace 1 in the arrangement is a suspension smelting furnace 1a, the arrangement may be configured to adjust the amount of gas that is blown into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2 based on the calculated sulfurization need.
In case the pyrometallurgical furnace 1 in the arrangement is a suspension smelting furnace 1a, the arrangement may be configured to adjust the amount of gas that is blown into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1 into the waste heat boiler 2 based on a measured residual oxygen content in the process gas 8.
The gas blowing means 7 are preferably, but not necessarily, provided at least partly in the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
The gas blowing means 7 are preferably, but not necessarily, configured to blow gas into the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
The gas blowing means 7 are preferably, but not necessarily, configured to blow gas into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c into the waste heat boiler 2 in the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
The gas blowing means 7 are preferably, but not necessarily, configured to blow gas from below into process gas 8 flowing from the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c into the waste heat boiler 2 in the connecting aperture 6 between the furnace space of the pyrometallurgical furnace 1; 1a; 1b; 1c and the waste heat boiler 2.
It is apparent to a person skilled in the art that as technology advanced, the basic idea of the invention can be implemented in various ways. The invention and its embodiments are therefore not restricted to the above examples, but they may vary within the scope of the claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 20135936 | Sep 2013 | FI | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/FI2014/050688 | 9/10/2014 | WO | 00 |
