DE20220946U1 - Reduction of nitrogen oxides from air stream comprises introducing cyanide into air stream, and reacting cyanide with nitrogen oxides - Google Patents

Abstract

Nitrogen oxides from an air stream is reduced by introducing cyanide into the air stream, and reacting the cyanide with the nitrogen oxides. An independent claim is included for a cement manufacturing system comprising a kiln that burns raw materials to produce a gas comprising a nitrogen oxide compound, a pre-heater tower coupled to the kiln, and a cyanide containing waste that reacts with the gas in the pre-heater tower to reduce the nitrogen oxide compound.

Description

background

NO _x is the term used when referring to a family of air polluting chemical compounds. Of the NO _x compounds, only nitrogen dioxide (NO ₂ ) is regulated by the Federal Environment Agency (EPA). NO ₂ is not only an air pollutant itself, it also reacts in the atmosphere and forms ozone (O ₃ ) and acid rain. While stratospheric ozone provides protection against solar radiation, it is necessary to reduce tropospheric ozone in the ambient air we breathe, since tropospheric ozone is a major component of smog. The EPA has introduced national quality standards for ambient air (NAAQS) for NO ₂ and tropospheric ozone. In addition, acid rain can have adverse effects on the ecosystem.

NO _x typically results from the combustion of certain fuels. Automobiles and power boilers are two major sources of NO _x , but substantial amounts of NO _x are released from waste incineration plants, iron and steel plants, glass factories, petroleum refineries, and cement manufacturers, to name a few. In particular, the combustion of coal during a cement manufacturing process is likely to result in the production and release of NO _x .

U.S. Patent 4,154,803 to Uchikawa et al. (May 1979) describes a method for reducing the nitrogen oxide content in a combustion exhaust gas by mixing the gas with a reagent material selected from ammonia, an ammonium salt, urea and an aqueous solution thereof. Through selective, non-catalytic reduction, the ammonia or other materials reduce the NO _x to water vapor and atmospheric nitrogen. The '803 patent specification further describes the implementation of this process on exhaust gas that develops during cement baking. U.S. Patent 4,307,068 to Matsumoto et al. (December 1981) also teaches methods for treating exhaust gases containing nitrogen oxides by adding ammonia to the exhaust gas. While the introduction of ammonia and some other materials can reduce the ratio of NO _x in exhaust gas, such a process is generally only effective in a narrow temperature range (1073K-1373K) and is often not a viable alternative due to its cost.

To reduce the cost of cement production, it is known to use waste products to add mineral components to the cement. U.S. Patent 5,496,404 to Price and Long (March 1996) teaches that paint waste can be used in the manufacture of Portland cement. The waste paint is introduced into the process after the raw materials have been fired. During the firing process, the raw materials chemically combine and partially fuse to form clumps of zemenz clinker. These lumps are usually finely ground to form Portland cement and during this milling step the '404 patent contemplates adding waste materials. In this case, the mineral content of the waste can be useful for Portland cement. There is a limitation to the addition of waste during milling that only a small amount of materials are useful at this point. The useful ^materials are generally limited to large amounts of calcium / small amounts of silicon material.

Another use for waste materials in the manufacture of cement involves large amounts of fuel waste that provides heat for the combustion process. In general, raw materials are burned in a kiln and this combustion process can be calcining, roasting, autoclaving or some other process, but in any case the process is generally carried out at approximately 2600 degrees Fahrenheit. U.S. Patent 4,081,285 to Pennel (March 1978) teaches that large amounts of fuel waste, such as oil-based paint, can be incinerated outside of the furnace to reach the required temperature. There is still a need to find waste to reduce the _NOx emissions associated with the production of cement.

Such a drop that has been used to reduce NO _{x to,} is sewage sludge. In U.S. Patent 5,586,510 to Leonard et al. (December 1996), aqueous sludge from wastewater is introduced into a kiln to reduce the ratio of NO _x in an exhaust gas generated during a cement manufacturing process. The use of a waste product to reduce NO _x has a dual advantage in that it helps the environment and is generally less expensive, but there is a need to use other waste materials, including non-aqueous waste materials, to use the exhaust gases effectively denitrify.

An alternative method for removing nitrogen oxides from gas produced by cement production includes the use of solid waste materials, as described in US Pat. No. 6,210,154 to Evans et al. (April 2001) reports a. The '154 patent describes methods of NO _x reduction by introducing waste tires into the manufacturing process at a point between the mineral inlet end of the rotary kiln and the bottom cyclone of a preheating system. It is further taught that the waste tires are in contact with the hot gas for a sufficient period of time to reduce the weight of the volatile combustible portion of the tires by at least 30%.

There is an ongoing need to find materials and methods using these materials that contribute to the manufacture of cement as well as reduce the amount of harmful NO _x released into the atmosphere during various methods.

Summary of the invention

The present invention is based on Systems and methods for reducing nitrogen oxides from an air stream, by introducing of cyanides in the air flow and reaction of the cyanides with the nitrogen oxides directed. In some embodiments the reaction takes place at a temperature between 649 ° C and 893 ° C (1200 ° F and 1640 ° F).

It should be noted that the object of the invention is introduced particularly for a cement production process in the cyanide-containing waste material in the process, both to reduce NO _x and to provide a mineral content, is useful.

Different objects, features, Aspects and advantages of the present invention will become apparent from the following detailed description of preferred embodiments of the invention with the attached Drawings in which like numbers represent like components, become clearer.

Brief description of the drawings

1 Figure 3 is a block diagram of a method for reducing nitrogen oxides.

2 is a schematic of a cement manufacturing system.

Detailed description

Referring first to 1 includes a process for reducing nitrogen oxides 100 the steps of producing an air stream with a nitrogen oxide by burning a raw material mixture in a kiln 110 , the introduction of a cyanide-containing waste material into the air stream 120 in a manner that causes the cyanide to react with the nitrogen oxides in the air stream at a temperature between 649 ° C and 893 ° C (1200 ° F and 1640 ° F), 130 and using a mineral residue of the waste material in one cement manufacturing process 140 ,

Nitrogen oxide (NO _x ) is a term that includes at least one of the following compounds: nitrous oxide (N ₂ O), nitrogen monoxide (NO), nitrous oxide (N ₂ O ₂ ), nitrous oxide (N ₂ O ₃ ), nitrogen dioxide (NO ₂ ) , Nitrous oxide (N ₂ O ₄ ) and nitrous oxide (N ₂ O ₅ ). An air stream with a nitrogen oxide is preferably a gas that has 200-1000 ppm NO _x , but the concentration of NO _x should not be interpreted as a limitation, since the reduction of NO _x would occur with much higher or lower concentrations.

A stream of air with a nitrogen oxide can be an exhaust gas resulting from a combustion process, such as that which occurs during the combustion of materials (e.g. limestone, silicon dioxide, iron ore and aluminum oxide) in a cement kiln. Generally, the combustion referred to here is the combustion of a fuel, such as coal, methane gas, oil, waste materials, etc. In a typical cement manufacturing process, the NO _x -rich gas rises up through a preheater tower and out of an exhaust stack.

When the NO _x rich gas rises, a cyanide-containing waste material is released into the air stream 120 introduced. Cyanide is defined herein as any of various salts or esters of hydrogen cyanide that contain a CN group, including potassium cyanide and sodium cyanide. This cyanide-containing waste can optionally be derived from mining processes that use a heap washout process. In a heap washing out process, the cyanide seeps through the mined material and as a result, a waste material that has a high mineral content (eg iron, aluminum and silicon dioxide) is produced. However, the waste material contains hydrogen cyanide, which is itself a highly toxic compound. By using this waste a two-time benefits can be achieved by the _NOx concentration is reduced and the desired mineral content is added. Waste containing cyanide is also a by-product of a process involving aluminum, in which a "crucible" comprising a steel housing lined with insulating material and a carbon layer is used, the carbon layer serving as a cathode for an electrolysis process. This process becomes in a likewise pending application, which was filed by the same inventor under the title "Use of Spent Potliners in Cement Production" and is fully incorporated here as a reference. It should be noted that under conditions in which moisture is present, ammonia (NH ₃ ) can be generated from the waste of the used crucible lining. This ammonia can be used to additionally or alternatively help reduce NO _x . Of course, the cyanide-containing waste can be derived from other processes, including an electroplating process and a chemical formulation process.

It is preferred that the waste material is in a non-aqueous form and the introduction of a cyanide-containing waste material 120 with the help of a fan that distributes the waste material into the air flow. Regardless of the type of introduction of the waste, sufficient ver mixing or close contact of the waste with the air flow, and the reaction of the cyanide with the nitrogen oxides 130 in a selective, non-catalytic reduction (SNCR) can take place. It should be noted that while an SNCR process is preferred, a selective catalytic reduction (SCR) process can also produce the desired results.

In a preferred class of embodiments, the reaction of the cyanide (ie, the reagent) and the NO _{x occurs} at a temperature between 649 ° C and 893 ° C (1200 ° F and 1640 ° F). With this preferred temperature range, it has been shown that the reduction of NO _x exceeds that caused by ammonia. The temperature range within which the reduction of NO _x occurs should be interpreted broadly, and justified variations in the temperature range as such can still give a favorable result.

In 2 includes an exemplary cement manufacturing system 200 a preheating and / or precalcination tower 210 , a waste inlet 220 , a riser pipe 230 , a rotary kiln 240 and a clinker cooler 250 , The relevant part of the system starts with the burning of raw materials in the kiln 240 where the temperature can reach 1482 ° C (2700 ° F) or more. Burning the raw materials is associated with fuel combustion, which generally produces NO _x in the furnace air stream. The air flow generally follows a path from the furnace up through the riser pipe to the preheating tower 210 and then from the exhaust stack. At an appropriate point along the way, a cyanide-containing waste will enter the airflow through the waste inlet 220 introduced. A point on the way is appropriate if the cyanide-containing waste mixes sufficiently with a NO _x -rich air stream to effect the reduction of the NO _x . While the introduction of the waste is presented so that it is directly in the preheating tower 210 occurs, it is intended that the waste inlet 220 at a point in front of the preheating tower 210 (ie in the riser 230 or even in the kiln 240 ), depending on the temperature.

It is contemplated that other factors other than the temperature at which the waste is introduced can affect the efficiency of NO _x reduction. Among these factors are the concentration of oxygen in the air stream, the retention time at suitable temperatures and the tightness of contact between the NO _x reducing factors and the NO _x compounds.

Thus, specific embodiments and applications of introducing cyanide waste as a NO _x reducing agent have been disclosed. However, it should be apparent to one of ordinary skill in the art that many other modifications besides those already described are possible without departing from the inventive concept above. The subject matter of the invention should therefore not be limited except in the light of the appended claims. In addition, both the interpretation of the description and the claims should be interpreted in the broadest possible sense that matches the context. In particular, the terms "comprising" and "comprising" should be interpreted as referring to the elements, components or steps in a non-exclusive manner, indicating that the related elements, components or steps may be or used or with others Elements, components or steps that are not expressly mentioned can be combined.

Claims (4)

A cement manufacturing system that includes: - one Kiln that burns raw materials, with a gas that comprises a nitrogen oxide compound is generated; - one preheating tower, which is coupled to the kiln; and - a waste containing cyanide, the one in the preheating tower reacts with the gas to reduce the nitrogen oxide compound. The system of claim 1, wherein the cyanide-containing Waste is obtained from waste mass. The system of claim 2, further comprising a waste entry port to the preheating tower introduction of the cyanide-containing waste in the preheating tower. The system of claim 3, wherein the temperature in the preheating tower at the point where the waste is introduced is between 649 ° C and 927 ° C (1200 ° F and 1700 ° F).