NL1002364C2 - Fluorine compound removal from gas streams - Google Patents

Abstract

Fluid is cleaned by formation of a slightly soluble salt. A gaseous phase produces the anion component of the salt and this is brought together with a liquid phase, containing the cation component, in a single reaction chamber. The salt then precipitates onto a solid phase.

Description

Method for cleaning a fluid

The present invention relates to a method of cleaning a fluid by forming a sparingly soluble salt, wherein a gaseous phase for providing the anion component of the salt and a liquid phase are brought into contact with each other, and the liquid phase in the presence of a cation-providing compound in a reaction space is contacted with a solid phase to precipitate the sparingly soluble salt formed from the cation component and the anion component on the solid phase.

Such a method is known in the art. For example, a fluorine-containing gas stream is washed with water to yield a fluoride ion-containing aqueous solution. The gaseous stream thus cleaned can be released into the atmosphere without damage to the environment. The fluoride ion-containing aqueous solution is then fed to a reactor. In the reactor, the fluoride ions are precipitated on a solid support using calcium ions. Such a method for precipitation as salt 20 is described in European patent 0 476 773.

The described method has the drawback that it comprises two devices and each process has to be controlled and monitored.

The object of the present invention is to provide an improved method of the type mentioned in the opening paragraph, wherein the drawbacks mentioned are eliminated.

To this end, the method according to the invention is characterized in that, for cleaning the fluid, the gaseous phase, the liquid phase and the solid phase are brought into contact in one reaction space.

A reactor is saved by performing the cleaning in one reaction space. The addition of the gaseous phase promotes mixing and contributes to a controlled crystallization process which prevents the formation of flocs with a high liquid content.

GWF-Wasser / Abwasser, 1988, 129 (5), pp. 327-339 discloses a method for removing iron from groundwater by dissolving oxygen in water, feeding this water to ferrous groundwater and after the to pump up hydrated ferric oxide groundwater. The matrix of negatively charged hydrated oxide surfaces acts as an adsorbent for ferrous ions and iron-depleted ground water can be recovered. This method also comprises more steps and has the further drawback that a continuous flow of cleaned fluid cannot be obtained. In contrast, the method according to the invention can advantageously be carried out continuously.

According to a preferred embodiment, the fluid is formed by the liquid phase which comprises an aqueous solution of a metal ion to be removed, the gaseous phase is a carbon dioxide-containing gas, and the metal ion forms with a carbon dioxide and water of the aqueous solution. carbonate ion on the solid phase is a metal ion carbonate.

Thus, metal ions can be inexpensively removed from an aqueous solution. The carbon dioxide-containing gas is advantageously a waste gas such as a combustion gas. Advantageously, the metal ion is a calcium ion or a heavy metal ion. For many applications, the removal of calcium means decreased scale build-up in pipes and on surfaces of, for example, heat exchangers, reducing maintenance costs and out-of-service time, while further reducing energy costs through lower pumping costs and better heat transfer.

The carbon dioxide-containing gas can advantageously also be a carbon dioxide-containing flammable gas, such as natural natural gas or biogas from an anaerobic reactor. It is thus not only possible to remove calcium or heavy metals, but also to increase the calorific value of the gas.

According to a preferred embodiment of the method according to the invention, the liquid phase is an anaerobic one

1 0 0 2 3 6 A

3 reactor to be supplied liquid. Anaerobic reactors often use microorganisms on supports, or other immobilized microorganisms, and the deposition of lime or the presence of heavy metal ions interferes with the reliable operation of the anaerobic reactor. According to the invention, these interfering components are removed before being fed to the anaerobic reactor using the carbon dioxide-containing biogas produced in the anaerobic reactor.

In another embodiment, the liquid phase comprises a calcium ion-containing aqueous solution, the fluid is formed by the gaseous phase which contains a volatile fluorine to be removed which forms fluoride ions on contact with water of the liquid phase, and fluoride ions with calcium ions on the solid phase calcium fluoride salt.

Examples of such fluorine compounds are fluorine, hydrogen fluoride, silicon fluorine compounds and uranium hexafluoride.

The process according to the invention can expediently be carried out in a fluidized bed reactor and advantageously the gaseous phase is introduced in an evenly distributed manner near the bottom of the fluidized bed reactor. The mixing of the three phases, and therefore the dust transfer, is thus promoted.

The invention will now be elucidated with reference to the figure, which schematically represents a possible application of the method according to the invention.

Reference numeral 1 denotes a fluidized bed reactor wherein a calcium-containing liquid stream is introduced via line 2 into the fluidized bed 1. In the fluidized bed 1 there is a solid carrier material on which insoluble calcium salt can precipitate. Carbon dioxide-containing gas is supplied via line 4 and distribution plate 5. In contact with the aqueous liquid phase, carbonate ions are formed and calcium carbonate precipitates on the solid support. Purified liquid is fed via line 6 to a U0236 * 4 anaerobic reactor 7. Biogas is formed by anaerobic digestion of organic material present in the calcium-depleted liquid. The calorific value of biogas is relatively low due to the presence of carbon dioxide. via line 4 the carbon dioxide-containing biogas is fed to the fluidized bed 1 where at least part of the carbon dioxide precipitates as calcium carbonate. Calorically enriched biogas is removed via line 3 for further use.

Since the liquid supplied to the anaerobic reactor 7 is depleted of calcium and possibly also of heavy metals, the operation of the anaerobic reactor 7 is improved, and anaerobically purified liquid can be discharged via line 8.

It is clear to the skilled person that the method according to the invention offers numerous perspectives. For example, an ammonia-containing gas can be used to form hydroxide ions and thus be used to remove heavy metals while avoiding ammonia from entering the atmosphere. An ammonia-containing gas can also be used to remove dissolved phosphates in a waste water stream by crystallization of magnesium ammonium phosphate. In this case a magnesium compound will have to be added to provide the cation, for example in the form of magnesium oxide or magnesium chloride.

With the method according to the invention flue gas can be desulphurised in one step to yield gypsum, for instance by using a calcium chloride solution as liquid phase. It has been found that gypsum of excellent quality can be obtained here because no or hardly any inclusion of heavy metals takes place. For effective cleaning, the pH does not have to be set as high, which of course reduces the costs for reagents.

Another possible application is the removal of hydrogen sulfide, for example from biogas. The hydrogen sulphide-containing gas is here passed through a solution 1002364 which contains very sparingly soluble metal sulphide-forming metal ions. This may include a relatively low-concentrated iron chloride solution. In contrast to the known methods for washing hydrogen sulphide-containing gas, the method according to the invention can be operated at a lower hydroxide ion concentration, which reduces costs. A lower hydroxide ion concentration is in particular also advantageous when washing a gas stream containing carbon dioxide, in addition to hydrogen sulfide, since less lye is lost by dissolving carbon dioxide.

In many industrial processes, the removal of calcium is important, and there are also numerous processes in which carbon dioxide-containing gas streams - for instance obtained by combustion of carbon-containing fuels for process heat - are available.

Although the process according to the invention can advantageously be carried out in a fluidized bed reactor, it is not limited thereto. Depending on the application, a packed bed reactor may be preferred.

20 1002364

Claims (11)

1. A method of cleaning a fluid by forming a sparingly soluble salt, whereby a gaseous phase for providing the anion component of the salt and a liquid phase are brought into contact with each other, and the liquid phase in the presence of a cation-providing compound in a reaction space is contacted with a solid phase to precipitate the sparingly soluble salt formed from the cation component and the anion component on the solid phase, characterized in that cleaning the fluid, the gaseous phase, the liquid phase and the solid phase are contacted in one reaction space. A method according to claim 1, characterized in that the fluid is continuously supplied to the reaction space. A method according to claim 1 or 2, characterized in that the fluid is formed by the liquid phase which comprises an aqueous solution of a metal ion to be removed, the gaseous phase is a carbon dioxide-containing gas, and the metal ion with a carbon dioxide and water of the aqueous solution formed carbonate ion on the solid phase forms a metal ion carbonate. A method according to claim 3, characterized in that the metal ion is a calcium ion. A method according to claim 3, characterized in that the metal ion is a heavy metal ion. A method according to any one of claims 2 to 5, characterized in that carbon dioxide-containing flammable gas is used as the carbon dioxide-containing gas. Process according to claim 6, characterized in that the combustible gas is biogas from an anaerobic reactor. Process according to claim 7, characterized in that the liquid phase is a liquid to be supplied to the anaerobic reactor. 1002364 9. Process according to claim 1 or 2, characterized in that the liquid phase comprises a calcium ion-containing aqueous solution, the fluid is formed by the gaseous phase which contains a volatile fluorine compound to be removed which, on contact with water, of the liquid phase forms fluoride ions, and the fluoride ions with calcium ions on the solid phase forms calcium fluoride salt. 10. A method according to any one of the preceding claims, characterized in that the cleaning is carried out in a fluidized threat actuator. A method according to claim 10, characterized in that the gaseous phase is introduced uniformly distributed near the bottom of the fluidized bed reactor. 1002364