DE2844274A1 - Double adsorption to remove pollutants from exhaust gases - having initial bed to remove sulphur tri:oxide followed by cooling and adsorption to remove the rest giving reduced corrosion - Google Patents

Abstract

Various pollutants are removed from exhaust gases by (a) first adsorber with an activated carbon bed to adsorb the SO3, (b) a second activated carbon bed to remove SO2 and nitrogen oxides, (c) a cooling stage between the first and second adsorbers to cool the exhaust gases, (d) lines between the various components to convey the gas. Removal of the SO3 drops the acid dew pt. of the gas to below that at which effective adsorption will take place in the second adsorber. To remove pollutants such as SO3, SO2, Nox etc. from exhaust gases to comply with environmental pollution regulations. The problem with SO3 is that it causes H2SO4 to condense out and cause severe corrosion. By effectively removing this at an elevated temp. the problem is greatly reduced.

Description

a. lvi 1 Z Q 4 4 Z / 4

13th

FOSTER WHEELER ENERGY CORPORATION, Livingston, N.J. VStA

Method and device for adsorbing contaminants

The invention relates to the removal of contaminants from exhaust gases and in particular the removal of sulfur and nitrogen oxides from exhaust gases with the help of nBhrerer adsorber with intermediate cooling.

Exhaust gas is generated by power plants and other industrial plants where the commonly available standing fuels made from hydrocarbons, such as for example coal and heating oil, can be burned in the presence of air. Various impurities are in present in the gas, such as sulfuric acid, nitrogen oxides and depending on the sulfur content of the fuel Sulfur oxides.

Air pollution regulations require that the contaminants, particularly sulfur and Trioxide, must be removed from the exhaust gas before it is released into the atmosphere. Practical considerations regarding the acid dew point of the exhaust gas and the preferred temperature range for effective removal sulfur dioxide and nitrogen oxides limit the effective removal of these contaminants. As is well known sulfur trioxide can be adsorbed extremely efficiently within a first temperature range while Sulfur dioxide and the nitrogen oxides are most effectively adsorbed within a second, lower temperature range will. It is also known that the exhaust gas has an acid dew point below which a corrosive one Acid is formed which affects the components that come with the exhaust gas

909816/0914

come into contact, attacks. The acid dew point is one Function of the concentration of sulfur trioxide and is generally above the preferred for most exhaust gases Temperature range for the effective adsorption of sulfur dioxide and nitrogen oxides. Generally will the temperatures of the exhaust gas above the acid dew point held in order to protect the components coming into contact with the exhaust gas, which of course leads to a reduction in the effectiveness of sulfur dioxide removal and Nitrogen oxides must be accepted.

The object of the invention is therefore to create a device and a method for effective removal the sulfur and nitrogen oxides from exhaust gases, whereby the risk of corrosive attack by acids is reduced will.

Another object of the invention is to provide an apparatus and a method for effective removal of sulfur trioxide from exhaust gases within a preferred temperature range for sulfur trioxide adsorption as well as for the effective removal of sulfur dioxide and nitrogen oxides from exhaust gases within one preferred for adsorption of sulfur dioxide and nitrogen oxides Temperature range, in particular the acid dew point of the exhaust gas to a value below that for adsorption the preferred temperature range of sulfur dioxide and nitrogen oxides can be lowered.

To solve these problems, the device according to the invention consists of a first adsorber, which is spatially is separated from a second adsorber, with an exhaust gas cooling unit between the first and second adsorber is arranged. The exhaust gas flows through the first adsorber within a range for the effective removal of Sulfur trioxide preferred temperature range is through

909816/0914

the cooling unit on one for the removal of sulfur dioxide and nitrogen oxides, the preferred temperature range is cooled and then flows through the second adsorber. The removal of sulfur trioxide in the first adsorber lowers the acid dew point of the exhaust gas to one Value below that for the removal of sulfur dioxide and nitrogen oxides preferred temperature range, which minimizes the risk of corrosive acid attack is depressed while at the same time enables effective adsorption of the sulfur dioxide and nitrogen oxides will.

The invention is explained below with reference to the description of a preferred embodiment or implementation explained in more detail in connection with the drawing, which represents a flow diagram of the device according to the invention.

According to the drawing, the device 10 according to the invention has a first adsorber as its main component 12, an exhaust gas cooling unit 14, a gas mixing device 16 and a second adsorber 18.

The adsorber 12 is of conventional design and includes an inlet chamber 20, an outlet chamber 22, a Coal inlet 24, a coal outlet 26 and two gas-permeable walls 28 and 30 arranged at a distance from one another with slanted slots. Each trench wall consists of a number of elongated slats 32, which in vertical Direction of each other and are arranged with their longitudinal axes parallel to each other, their flat Surfaces are inclined to the horizontal. The adsorber 12 can absorb activated carbon, preferably in Form of discrete activated charcoal pellets which are introduced through charcoal inlet 24 with the charcoal in the space between the two slotted walls 28 and 30 with training

909818/0014

formation of a bed B1 of adsorbing activated carbon accumulates. The activated carbon is from the first adsorber 12 .by the Carbon outlet 26 removed with the downward velocity of the activated carbon bed B1 using a conventional vibrating magnet feeder 34 is controlled. The adsorber 12 is arranged so that it through, its inlet chamber 20 exhaust gas receive and the exhaust gas through the slit wall 28 in and through the activated carbon bed B1, through the slit wall 30 and can lead into the outlet chamber 22.

Adjacent to and in communication with the inlet chamber 20 of the adsorber 12 is an exhaust gas dilution device 36 of FIG conventional design arranged. The dilution device 36 is set up so that the hot exhaust gas with cooler. Air can be mixed from a source not shown can to cool the exhaust gas to a preferred temperature range before it enters the inlet chamber 20 of the first adsorber 12 arrives. The adsorber 18, which is also of conventional design, but larger than the adsorber 12 comprises an inlet chamber 38, an outlet chamber 40, a coal inlet 42, a coal outlet 44 and two of each other spaced gas-permeable slot walls 46 and 48. The adsorber 18 is arranged so that he receives activated carbon fed through his carbon inlet 42 and this in the space between the two Holds slot walls 46 and 48 in the form of a bed B2 of adsorbing activated carbon. The activated carbon is made from the Adsorber 18 removed through the carbon outlet 44, the downward speed of the activated carbon bed B2 with the help a conventional vibratory magnetic feeder 50 is controlled. The adsorber 18 is set up so that it receive exhaust gas through its inlet chamber 38 and this through the slit wall 46 into and through the bed B2 made of activated carbon, through the slit wall 48 and into the outlet chamber 40.

909816/0914

In addition to and in connection with the outlet chamber 40 of the adsorber 18, a fan 52 is angeodnet to the exhaust gas from the adsorber 1.8 with to remove and it in a (not shown ^ to convey the exhaust chimney.

The exhaust cooling unit 14, which in a preferred embodiment is a water spray cooling device arranged between adsorber 12 and adsorber 18. The cooling unit 14 consists of a number of water spray heads 44, which received water from a source (not shown) and produced a finely atomized mist in the exhaust gas Spray water droplets. A valve 56 is provided in a water supply pipe 58 to control the flow rate of the water to the cooling unit 14 to control. While in the preferred embodiment a water spray cooling unit other types of refrigerants, including water evaporators, Regeneration heat exchangers and tubular heat exchangers can be used.

A gas mixing unit 16 of conventional design is also provided between the cooling unit 14 and the adsorber 18, to mix the exhaust gas and the water mist generated by the cooling unit 14 with each other so as to be uniform To ensure cooling of the gas.

For measuring the temperature of the exhaust gas after it has been cooled and for generating feedback control signals for the valve 56 to increase or decrease the flow of water to the cooling unit 14 and thereby to automatically control the temperature of the exhaust gas as it flows through the cooling unit 14, a temperature control device, not shown, is also provided.

909816/0914

28U274

- ίο -

The carbon inlet 24 of the adsorber 12 and the carbon inlet 42 of the adsorber 18 are both connected to a carbon line 60 which carries a stream of regenerated activated carbon from an activated carbon source (not shown) to the adsorbers 12 and 18. In an analogous manner, the feeder 34 of the adsorber 12 and the feeder 50 of the adsorber 18 are connected to an activated carbon line 62, which leads a flow of activated carbon loaded with impurities from the adsorbers 12 and 18 to an activated carbon regeneration device or the like, not shown.

Although not explained in detail in the drawing, the main individual parts of the invention Device in connection with each other via suitable lines, which in the drawing only by the horizontal Line 66 are shown schematically. The lines 66 lead the exhaust gas flow through from left to right the main components of the device according to the invention.

The device is suitable in the manner described below, sulfur dioxide, sulfur trioxide and Remove nitrogen oxides from exhaust gas. The sulfur trioxide is preferred within one for its effective removal Temperature range removed, after which the gas on the one for the effective removal of sulfur dioxide and nitrogen oxides preferably a temperature range is cooled. By removing the sulfur trioxide in the adsorber 12 at the beginning the acid dew point of the gas to a value below that for effective removal of sulfur dioxide and the Nitrogen oxides preferred temperature range and thereby an effective removal of these impurities while avoiding the difficulties caused by an attack by corrosive acid, enables.

309818/0914

28U274

In operation, fresh gas, the sulfur dioxide, sulfur trioxide and nitrogen oxides contains, from a source not shown with a temperature in the range of 138 - (- 400 ⁰ F 280) received 204 ° C. The gas enters the dilution device 36 through the lines 66 and, if desired, is mixed with cool air which enters the dilution device 36 from an air source (not shown). The exhaust gas is at a preferred temperature range of 138 - cooled - (325 ⁰ P 280) and passed through lines 66 into the inlet chamber of the adsorber 12 where it is passed through the slot wall 28 in the bed B1 of active carbon 163 ° C. Since sulfur trioxide is advantageously adsorbed in the temperature range just described, the sulfur trioxide concentration is reduced considerably by the exhaust gases. The exhaust gas passes through and out of the bed B1 of activated carbon and is passed through the slit wall 30 into the outlet chamber 22 of the adsorber 12. Thereafter, it is fed through the pipes 66 of the cooling unit 14, where the water droplets adsorb therefrom heat so that the gas to a preferred temperature range of 93.3 - 121.1 ⁰ C (200 - 250 ° F is cooled thereafter, the gas is with. The cooled mixed gas is then fed via conduits into the inlet chamber 38 of the adsorber 18, where it is directed through the slit wall 46 into the bed B2 of activated carbon are adsorbed to advantage in the temperature range just described, the concentrations of these two impurities are considerably reduced in the activated carbon bed B2 The exhaust gas, which is essentially free of impurities, is then passed through the slit wall 48 into the outlet chamber 40 of the adsorber 18 and from there fed to the fan 52, by means of which it is conveyed into an exhaust chimney, not shown.

909816/0914

Since the acid dew point of the exhaust gas increases as the sulfur trioxide concentration increases, the causes the Removal of a significant portion of the sulfur trioxide in adsorber 18 is a reasonable reduction in the Acid dew point of the exhaust gas. As can be seen enables the acid dew point to be lowered a temperature below the temperature range preferred for the adsorption of sulfur dioxide and nitrogen oxides the removal of a significant proportion of these contaminants by the adsorber 18 without the difficulties associated with attack by corrosive acid.

Various changes and modifications can of course be made to the device according to the invention can be made within the scope of the invention.

90981 6 / 09U

Claims (17)

Br.-Ing. V * i int. · 3 ßeichel KA V ^ ».: V? -JJiJ Bd (M 9213 6 Fran & uAi a. M. 1" ™ Faxksiraife 13 FOSTER WHEELER ENERGY CORPORATION, Livingston ^. N.J., VStA. 1. Device for successive adsorption various pollutants from exhaust gas, consisting of a first adsorber (12) with a first bed (B1) Activated carbon to adsorb sulfur trioxide from the gas, a second adsorber (18) with a second bed (B2) of activated carbon for the adsorption of sulfur dioxide and nitrogen oxides from the gas, Coolant means (14) which are arranged between the first and the second adsorber for cooling the exhaust gas, and Lines (66) for conveying the gas through the first adsorber, from the adsorber to the coolants and from the coolants to the second adsorber, wherein the adsorption of the sulfur trioxide reduces the acid dew point of the exhaust gas to a value below the temperature of the exhaust gas, that flows through the second adsorber lowers. 2. Device according to claim 1,
characterized gekennzei seframe that the cooling means (14) (F ⁰ 200 and 250) are adapted to cool the gas to a temperature substantially 93.3 to 121.1 ⁰ C. 909818/0914 ORIGINAL INSPECTED 3. Device according to claim 1,
characterized in that the coolants (14) are arranged between the first (B1) and the second (B2) bed of activated carbon. 4. Device for the successive adsorption of various contaminants from exhaust gas, consisting of Means defining a first bed (B1) of activated carbon, to absorb the exhaust gas and adsorb the sulfur trioxide it contains to lower the acid dew point the exhaust gas to a predetermined value, Means defining a second bed (B2) of activated carbon, parallel to and at a distance from the first Bed of activated carbon extends, for the adsorption of sulfur dioxide and nitrogen oxides from the gas, Means (14) for cooling the exhaust gas to a temperature, which is on the one hand above the acid dew point of the gas and on the other hand is sufficiently deep to allow adsorption of sulfur dioxide and nitrogen oxides, and Means (66) for directing the exhaust gas from the first bed (B1) of activated carbon to the coolant means (14) and from the Coolants in the second bed (B2) of activated carbon. 5. Apparatus according to claim 1 or 4, characterized in that the coolant (14) means (54) for generating a Mist of water droplets in the gas for transferring the heat from the gas to the water droplets and cooling contained in the gas. 6. Device according to claim 5,
characterized in that it also includes a gas mixing device (16) between the mist generating means (54) and the second adsorber (18) for mixing gas and mist. 909816/0914 7. The device according to claim 1, characterized in that it also has second coolants (36), which are in communication with an inlet chamber (20) of the first adsorber (12), for cooling the exhaust gas to a temperature essentially between 138 and 163 ⁰ C (280 and 325 ° F) contains. 8. Device according to claim 7, d.a characterized in that the second coolant (36) means for admixing contain cooler air to the exhaust gas and thereby to cool the exhaust gas. 9. Device according to claim 1 or 4, characterized in that that the exhaust pipes (66) are arranged such that they guide the exhaust gas in a practically horizontal direction. 10. The device according to claim 1, characterized in that the second adsorption stage (18) is greater than the first (12) is. 11. Method for sequentially adsorbing various contaminants from exhaust gas, characterized in that one keeps a first and a second bed of activated carbon parallel and at a distance from one another, in the first bed the sulfur trioxide contained in the exhaust gas with lowering of the acid dew point of the gas adsorbed to a predetermined value, the gas to a temperature above the predetermined Acid dew point cools and adsorbs sulfur dioxide contained in the gas as well as nitrogen oxides contained in it in the second bed. 12. The method according to claim 11, characterized in that the gas is cooled to a temperature of 93.3-121.1 ° C (200-250 ⁰ F) during cooling. 13. The method according to claim 11, characterized in that a mist of water droplets is used in the gas for cooling generated to transfer heat from the gas to the droplets while cooling the gas. 14. The method according to claim 13 » characterized in that one also mixes the mist and the gas with one another. 15. The method according to claim 11, characterized in that the gas is also used before the sulfur trioxide adsorption stage cools to a preferred temperature range for sulfur trioxide adsorption. 16. The method according to claim 15, characterized in that the range of 138-163 ⁰ C (280-325 ° F) is selected as the temperature range for the adsorption of sulfur trioxide. 17. The method according to claim 15, characterized in that that when the gas is cooled to the preferred temperature for the sulfur trioxide adsorption, the gas is cooler Air diluted. 909816/0914